CN111372302A - Communication method and device - Google Patents

Abstract

The application discloses a communication method and equipment. In the method, a terminal receives a power consumption saving signal sent by network equipment, wherein the power consumption saving signal indicates N time units, and N is greater than 0; the terminal determines the state of the terminal in a first time interval corresponding to N time units on a first frequency domain resource and the state of the terminal in a second time interval corresponding to N time units on a second frequency domain resource; the state of the terminal comprises a sleep state or an awakening state, the sleep state represents that the terminal does not monitor the first signal, and the awakening state represents that the terminal monitors the first signal according to the configuration parameters. By the method, the network device can only send the power consumption saving signal once, and the terminal can determine the sleep time or the wake-up time on different frequency domain resources according to the power consumption saving signal.

Description

Communication method and device

Technical Field

The present application relates to the field of communications technologies, and in particular, to a communication method and device.

Background

The standby time of the terminal is an important part affecting the user experience. Since a 5G New Radio (NR) system needs to support a bandwidth, a higher transmission rate, and a wider coverage than that of a Long Term Evolution (LTE) system, the power consumption of the NR terminal is greater than that of the LTE terminal. In order to ensure good user experience, the 3rd generation standardization organization (3 GPP) has made a special project in Rel-16 for the problem of saving terminal power consumption, and studies an optimization scheme for reducing terminal power consumption.

In order to achieve the purpose of energy saving, the method can be optimized from two aspects: firstly, when a service load exists (namely data needs to be transmitted), the data transmission efficiency is improved; and secondly, when no service load exists, the energy consumption is reduced. For the second point, it is mentioned in the report of international telecommunication union-radio communication group (ITU-R) that the reduction of the power consumption can be achieved by increasing the proportion of the terminals in the sleep state.

Disclosure of Invention

The embodiment of the application provides a communication method, which is used for enabling a terminal to determine sleep time or wake-up time on different frequency domain resources according to a power consumption saving signal.

In a first aspect, an embodiment of the present application provides a communication method, including:

the network equipment sends a power consumption saving signal to the terminal, wherein the power consumption saving signal indicates N time units, and N is a number greater than 0; after receiving the power saving signal, the terminal determines a state of the terminal in a first time period corresponding to the N time units on the first frequency domain resource and a state of the terminal in a second time period corresponding to the N time units on the second frequency domain resource. The state refers to a sleep state or an awakening state, the sleep state indicates that the terminal does not monitor the first signal, and the awakening state indicates that the terminal monitors the first signal according to the configuration parameters.

In the above embodiment, after receiving the power consumption saving signal, the terminal determines the time periods corresponding to the N time units indicated by the signal on different frequency domain resources, instead of simply determining that the sleep time or the wake-up time on different frequency domain resources are both N time units. The states of the terminals on different frequency domain resources are close to synchronization, so that the power consumption is saved.

In a possible implementation manner, the absolute duration of the first time interval on the first frequency domain resource may be equal to or approximately equal to the absolute duration of the N time units, and the absolute duration of the second time interval on the second frequency domain resource may be equal to or approximately equal to the absolute duration of the N time units.

In a possible implementation manner, the time unit indicated by the power consumption saving signal is a time slot, the duration of the first period is N time slots of the first frequency domain resource, and the terminal determines the duration of the second period according to the subcarrier interval configured by the first frequency domain resource, the subcarrier interval configured by the second frequency domain resource, and N. In this embodiment, the network device uses the first frequency domain resource as a reference, the indicated N time slots are N time slots on the first frequency domain resource, and the terminal further determines a duration of a second period corresponding to the N time slots on the first frequency domain resource.

In one possible implementation, the absolute durations of the N time slots on the first frequency domain resource may be determined, and the number of time slots on the second frequency domain resource equal to or approximately equal to the absolute durations may be determined.

In one possible implementation, the subcarrier spacing of the first frequency domain resource allocation is 15 × 2^M1kHz, subcarrier spacing of the second frequency domain resource allocation is 15 x 2^M2kHz, wherein M1 and M2 are integers greater than or equal to 0; the terminal determines the duration of the second time interval to be N x 2 on the second frequency domain resource^M2-M1A time slot, or

A time slot, or

And a time slot. Furthermore, M2 is more than or equal to M1, so that the duration of the second time interval is an integer number of time slots, the situation of non-integer number of time slots is avoided, and the terminal operation is convenient.

In a possible implementation manner, the terminal determines the duration of the second time period by looking up a table according to the subcarrier interval of the first frequency domain resource, the subcarrier interval of the second frequency domain resource, and N.

In a possible implementation manner, the time unit indicated by the power consumption saving signal is a time slot; the method further comprises the following steps: before sending the power saving signal, the network device also sends first configuration information to the terminal, where the first configuration information includes a reference subcarrier interval of the power saving signal. The terminal determines the duration of the first time period according to the reference subcarrier interval, the subcarrier interval of the first frequency domain resource and the N time units, and determines the duration of the second time period according to the reference subcarrier interval, the subcarrier interval of the second frequency domain resource and the N time units.

In one possible implementation, the absolute duration of the N time slots in the case of the reference subcarrier spacing may be determined, the number of time slots on the first frequency domain resource equal or approximately equal to the absolute duration may be determined, and the number of time slots on the second frequency domain resource equal or equal to the absolute duration may be determined.

In a possible implementation, the reference subcarrier spacing is 15 × 2^M0kHz, subcarrier spacing of said first frequency domain resource configuration 15 x 2^M1kHz, subcarrier spacing of said second frequency domain resource configuration 15 x 2^M2kHz; the terminal determines the duration of the first time interval to be N x 2 on the first frequency domain resource^M1-M0A time slot, or

A time slot, or

A time slot; the duration of the second time interval is N x 2 on the second frequency domain resource^M2-M0A time slot, or

A time slot, or

And a time slot. Furthermore, M1 is more than or equal to M0, and M2 is more than or equal to M0, so that the duration of the first time interval and the duration of the second time interval can be an integer number of time slots, the situation of non-integer number of time slots is avoided, and the terminal operation is convenient.

In a possible implementation manner, if the duration of the first period is a non-integer number of time slots and/or the duration of the second period is a non-integer number of time slots, the terminal reports an error to the network device. The terminal may not expect the durations of the first period and the second period to be non-integer time slots, and therefore, if the terminal determines that the durations of the first period and/or the second period are non-integer time slots, the terminal does not perform corresponding sleep or wake-up operations but reports an error to the network device. Correspondingly, the network device may also estimate the durations of the first period and the second period in advance, so as to make the first period and the second period corresponding to the N time units as an integer number of time slots as much as possible.

In a possible implementation manner, the terminal determines the duration of the first time period according to the reference subcarrier interval, the subcarrier interval of the first frequency domain resource and the N table lookup; and determining the duration of the second time interval by table look-up according to the reference subcarrier interval, the subcarrier interval of the second frequency domain resource and the N.

In one possible implementation manner, the starting time of the first period is a first time slot on the first frequency domain resource after the power consumption saving signal is received, and the starting time of the second period is a first time slot on the second frequency domain resource after the power consumption saving signal is received; or the starting time of the first period is a time slot on the first frequency domain resource when the power saving signal is received, and the starting time of the second period is a time slot on the second frequency domain resource when the power saving signal is received.

In one possible implementation, the first time interval and the second time interval are composed of consecutive time slots.

In a possible implementation manner, the time unit indicated by the power saving signal is a monitoring opportunity, since the terminal may not continuously monitor the first signal according to the configuration parameter, for example, the first signal is monitored on the first symbol or the first symbols in each time slot, or the first signal is monitored on the first symbols of every two time slots, and a time when the first signal is monitored in one monitoring period is referred to as a monitoring opportunity.

The duration of the first period is N monitoring cycles on the first frequency domain resource, or N × L1 time slots, where L denotes that the monitoring cycle of the terminal on the first frequency domain resource is L1 time slots, and L1 is an integer greater than or equal to 1. The network device uses the first frequency domain resource as a reference, and the indicated N monitoring occasions are N monitoring occasions on the first frequency domain resource. In a monitoring period, the terminal monitors the first signal at the monitoring opportunity, and does not monitor the first signal at other time intervals, so that if the network device indicates that the terminal does not monitor at the next monitoring opportunity, the terminal does not monitor the first signal at the next monitoring period, so that the network device indicates that the N monitoring opportunities are not monitored, and the terminal does not monitor at the N monitoring periods.

In one possible implementation, the absolute durations of the N monitoring periods on the first frequency domain resource may be determined, and the number of monitoring periods on the second frequency domain resource equal to or approximately equal to the absolute durations may be determined.

In one possible implementation, the subcarrier spacing of the first frequency domain resource allocation is 15 × 2^M1kHz, subcarrier spacing of the second frequency domain resource allocation is 15 x 2^M2kHz, wherein the monitoring period of the terminal on the second frequency domain resource is L2 time slots, wherein M1 and M2 are integers which are greater than or equal to 0, and L2 is an integer which is greater than or equal to 1; the duration of the second period is on the second frequency domain resource

A monitoring period of, or

A monitoring period of, or

One monitoring period, or NxL 1 x 2^M2-M1A time slot, or

A time slot, or

And a time slot. Furthermore, M2 is more than or equal to M1, so that the duration of the second time interval is an integer number of time slots, the situation of non-integer number of time slots is avoided, and the terminal operation is convenient.

In a possible implementation manner, the terminal may determine the duration of the second time period by looking up a table according to the subcarrier spacing of the first frequency domain resource, the monitoring period on the first frequency domain resource, the subcarrier spacing of the second frequency domain resource, the monitoring period on the second frequency domain resource, and N.

In a possible implementation manner, the time unit indicated by the power consumption saving signal is a monitoring opportunity; the method further comprises the following steps: the network device sends second configuration information to the terminal before sending the power saving signal, wherein the second configuration information comprises a reference subcarrier interval and a reference monitoring period of the power saving signal. The terminal determines the duration of a first time period according to the reference subcarrier interval, the subcarrier interval of the first frequency domain resource, the reference monitoring period, the monitoring period of the terminal on the first frequency domain resource and the N; and determining the duration of the second time interval according to the reference subcarrier interval, the subcarrier interval of the second frequency domain resource, the reference monitoring period, the monitoring period of the terminal on the second frequency domain resource and the N.

In one possible implementation, the absolute durations of the N monitoring periods with the reference subcarrier spacing and the reference monitoring period may be determined, the number of monitoring periods equal to or approximately equal to the absolute duration on the first frequency domain resource may be determined, and the number of monitoring periods equal to or equal to the absolute duration on the second frequency domain resource may be determined.

In one possible implementation, the reference subcarrier spacing is 15 x 2^M0kHz, a reference monitoring period is L0 time slots, M0 is an integer greater than or equal to 0, and L0 is an integer greater than or equal to 1; the subcarrier spacing of the first frequency domain resource allocation is 15 x 2^M1kHz, subcarrier spacing of the second frequency domain resource allocation is 15 x 2^M2kHz; the monitoring period of the terminal on the first frequency domain resource is L1 time slots, the monitoring period of the terminal on the second frequency domain resource is L2 time slots, wherein M1 and M2 are integers which are greater than or equal to 0, and L1 and L2 are integers which are greater than or equal to 1. The terminal determines that the duration of the first time interval is on the first frequency domain resource

A monitoring period of, or

A monitoring period of, or

One monitoring period, or NxL 0 x 2^M1-M0A time slot, or

A time slot, or

A time slot; the determined duration of the second time interval is on the second frequency domain resource

A monitoring period of, or

A monitoring period of, or

One monitoring period, or NxL 0 x 2^M2-M0A time slot, or

A time slot, or

And a time slot. Furthermore, M1 is more than or equal to M0, and M2 is more than or equal to M0, so that the duration of the first time interval and the duration of the second time interval can be an integer number of time slots, the situation of non-integer number of time slots is avoided, and the terminal operation is convenient.

In a possible implementation manner, if the first time period is a non-integer number of monitoring cycles and/or the second time period is a non-integer number of monitoring cycles, the terminal reports an error to the network device. The terminal may not expect the durations of the first time period and the second time period to be the non-integer number of monitoring cycles, and therefore, if the terminal determines that the durations of the first time period and/or the second time period are the non-integer number of monitoring cycles, the terminal does not perform corresponding sleep or wake-up operations and reports an error to the network device. Correspondingly, the network device may also estimate the durations of the first time period and the second time period in advance, so that the first time period and the second time period corresponding to the N time units are an integer number of monitoring cycles as much as possible.

In a possible implementation manner, the terminal may determine the duration of the first time period by looking up a table according to the reference subcarrier interval, the subcarrier interval of the first frequency domain resource, the reference monitoring period, the monitoring period of the terminal on the first frequency domain resource, and the N; and determining the duration of the second time interval by looking up a table according to the reference subcarrier interval, the subcarrier interval of the second frequency domain resource, the reference monitoring period, the monitoring period of the terminal on the second frequency domain resource and the N.

In one possible implementation, the starting time of the first time period is a first monitoring opportunity on the first frequency domain resource after receiving the power saving signal, and the starting time of the second time period is a first monitoring opportunity on the second frequency domain resource after receiving the power saving signal; or the starting time of the first time period is a first time slot on the first frequency domain resource after the power consumption saving signal is received, and the starting time of the second time period is a first time slot on the second frequency domain resource after the power consumption saving signal is received; or the starting time of the first period is a time slot on the first frequency domain resource when the power saving signal is received, and the starting time of the second period is a time slot on the second frequency domain resource when the power saving signal is received.

In a possible implementation manner, the time unit indicated by the power consumption saving signal is a connected-discontinuous reception (C-DRX) cycle, the C-DRX cycle of the first frequency domain resource configuration is K1 absolute time units, and K1 is an integer greater than or equal to 1; the terminal determines that the duration of the first period is N C-DRX cycles on the first frequency domain resource, or N x K1 absolute times; and the terminal determines the second period duration according to the C-DRX cycle configured by the terminal at the first frequency domain resource, the C-DRX cycle configured by the terminal at the second frequency domain resource and the N. The absolute time unit may be milliseconds (ms), seconds(s), and the like.

In one possible implementation, the absolute duration of the N C-DRX cycles on the first frequency domain resource may be determined, and the number of C-DRX cycles on the second frequency domain resource that is equal or approximately equal to the absolute duration may be determined.

In one possible implementation manner, the C-DRX cycle of the second frequency domain resource configuration is K2 absolute time units, and K2 is an integer greater than or equal to 1; the duration of the second period is a unit of N × K1/K2C-DRX cycles, or N × K1 absolute times, on the second frequency domain resource.

In one possible implementation manner, the terminal may determine the duration of the second period by looking up a table according to the C-DRX cycle on the first frequency domain resource, the C-DRX cycle on the second frequency domain resource, and N.

In a possible implementation manner, the time unit indicated by the power consumption saving signal is a C-DRX cycle, and the method further includes: the network device sends third configuration information to the terminal before sending the power saving signal to the terminal, wherein the third configuration information includes that the reference C-DRX cycle of the power saving signal is K0 absolute time units. The terminal determines the duration of a first period according to the reference C-DRX period, the C-DRX period configured by the terminal in the first frequency domain resource and the N; and the terminal determines the duration of the second period according to the reference C-DRX period, the C-DRX period configured by the terminal in the second frequency domain resource and the N.

In one possible implementation, the absolute duration of the N C-DRX cycles with reference to the C-DRX cycle may be determined, the number of C-DRX cycles on the first frequency domain resource equal to or approximately equal to the absolute duration may be determined, and the number of C-DRX cycles on the second frequency domain resource equal to or equal to the absolute duration may be determined.

In one possible implementation manner, the C-DRX period of the first frequency domain resource configuration is K1 absolute time units, the C-DRX period of the second frequency domain resource configuration is K2 absolute time units, and K1 and K2 are integers greater than or equal to 1. The terminal determines that the duration of the first time interval is a unit of N × K0/K1C-DRX cycles or N × K0 absolute times on the first frequency domain resource; the duration of the second period is a unit of N × K0/K2C-DRX cycles, or N × K0 absolute times, on the second frequency domain resource.

In a possible implementation manner, if the first period is a non-integer number of C-DRX cycles and/or the second period is a non-integer number of C-DRX cycles, the terminal reports an error to the network device. The terminal may not expect the durations of the first period and the second period to be non-integer C-DRX cycles, and therefore, if the terminal determines that the durations of the first period and/or the second period are non-integer C-DRX cycles, the terminal does not perform a corresponding sleep or wake-up operation and reports an error to the network device. Correspondingly, the network device may also estimate the durations of the first period and the second period in advance, so as to make the first period and the second period corresponding to the N time units as an integer number of C-DRX cycles as much as possible.

In one possible implementation, the terminal may determine the duration of the first period according to a reference C-DRX cycle, a C-DRX cycle on the first frequency domain resource, and an N lookup table; the terminal may determine the duration of the second period based on the reference C-DRX cycle, the C-DRX cycle on the second frequency domain resource, and the N look-up table.

In one possible implementation, the start time of the first period is a start time of a next C-DRX on the first frequency domain resource after receiving the power consumption saving signal, and the start time of the second period is a start time of a next C-DRX on the second frequency domain resource after receiving the power consumption saving signal.

In one possible implementation, the network device sends a power saving signal to the terminal on the first frequency domain resource, and correspondingly, the terminal receives the power saving signal on the first frequency domain resource.

In one possible implementation, the first frequency domain resource is a first carrier, and the second frequency domain resource is a second carrier; alternatively, the first frequency-domain resource is a first bandwidth part (BWP), and the second frequency-domain resource is a second BWP.

In a possible implementation manner, the first BWP is a primary BWP or a BWP on a primary carrier.

In a possible implementation manner, the first signal is one or more of the following signals: PDCCH, channel state information reference signal (CSI-RS), Synchronization Signal Block (SSB).

In a possible implementation manner, the power saving signal is sent to the terminal through Downlink Control Information (DCI), and the DCI includes scheduling information for scheduling uplink data or downlink data. The starting time of the first period is a time slot in which a power consumption saving signal is received, or a first symbol or a first time slot after a last symbol of downlink data is received, or a first symbol or a first time slot after a terminal sends ACK/NACK, or a terminal sends ACK/NACK and waits for a first symbol or a first time slot after a preset duration, and the terminal does not receive scheduling information of the network device within the preset duration, or a time slot in which a power consumption saving signal is received, or a first symbol or a first time slot after a last symbol of uplink data is sent, or a first symbol or a first time slot after sending uplink data and waiting for a first preset duration, and the terminal does not receive scheduling information of the network device within the preset duration.

In a possible implementation manner, the preset duration is configured for the terminal by the network device.

In a second aspect, an embodiment of the present application provides a communication method, including:

the network equipment sends a power consumption saving signal to the terminal, wherein the power consumption saving signal indicates N time units, and N is a number greater than 0; after receiving the power consumption saving signal, the terminal determines the state of the terminal in a first time interval corresponding to the N time units on the first frequency domain resource and the state of the terminal in a second time interval corresponding to the N time units on the second frequency domain resource; the state is a sleep state or an awakening state, the sleep state represents that the terminal does not measure, and the awakening state represents that the terminal measures according to the configuration parameters.

The determination manners of the durations of the first time interval and the second time interval and the start time are similar to the implementation manner in the first aspect, and are not described herein again.

In a third aspect, an embodiment of the present application further provides a communication device, where the terminal includes a receiving unit and a processing unit.

The receiving unit is used for receiving a power consumption saving signal sent by the network equipment, wherein the power consumption saving signal indicates N time units, and N is an integer greater than 0;

the processing unit is configured to determine, according to the power consumption saving signal, a state of the communication device in a first time period corresponding to the N time units on a first frequency domain resource and a state in a second time period corresponding to the N time units on a second frequency domain resource; the state is a sleep state or an awake state, the sleep state indicates that the communication device does not monitor the first signal, and the awake state indicates that the communication device monitors the first signal according to the configuration parameter.

In a possible implementation manner, the time unit is a time slot, and the duration of the first period is N time slots of the first frequency domain resource; and the duration of the second time interval is determined according to the subcarrier interval configured by the first frequency domain resource, the subcarrier interval configured by the second frequency domain resource and the N time units.

In a possible implementation manner, the subcarrier spacing of the first frequency domain resource configuration is 15 × 2^M1kHz, subcarrier spacing of said second frequency domain resource configuration 15 x 2^M2kHz, wherein M1 and M2 are integers greater than or equal to 0; the duration of the second time interval is N x 2 of the second frequency domain resource^M2-M1A time slot, or

A time slot, or

And a time slot.

In one possible implementation, the time unit is a time slot; the receiving unit is further configured to receive first configuration information sent by a network device before receiving the power consumption saving signal sent by the network device, where the first configuration information includes a reference subcarrier interval of the power consumption saving signal;

the processing unit is specifically configured to: determining the duration of the first time period according to the reference subcarrier interval, the subcarrier interval of the first frequency domain resource allocation and the N time units; and determining the duration of the second time period according to the reference subcarrier interval, the subcarrier interval configured by the second frequency domain resource and the N time units.

In one possible implementation, the reference subcarrier spacing is 15 x 2^M0kHz, subcarrier spacing of said first frequency domain resource configuration 15 x 2^M1kHz, subcarrier spacing of said second frequency domain resource configuration 15 x 2^M2kHz; the duration of the first time interval is N x 2 of the first frequency domain resource^M1-M0A time slot, or

A time slot, or

A time slot; the duration of the second time interval is N x 2 of the second frequency domain resource^M2-M0A time slot, or

A time slot, or

And a time slot.

In one possible implementation, the time unit is a monitoring opportunity; the duration of the first period is N monitoring cycles on the first frequency domain resource, or N × L1 time slots, where L denotes that the monitoring cycle on the first frequency domain resource of the communication device is L1 time slots, and L1 is an integer greater than or equal to 1; the duration of the second time interval is determined according to the subcarrier interval configured by the first frequency domain resource, the subcarrier interval configured by the second frequency domain resource, the monitoring period of the communication device on the first frequency domain resource, the monitoring period of the communication device on the second frequency domain resource, and the N time units.

In a possible implementation manner, the subcarrier spacing of the first frequency domain resource configuration is 15 × 2^M1kHz, subcarrier spacing of said second frequency domain resource configuration 15 x 2^M2kHz, a monitoring period of the communication device on the second frequency domain resource is L2 time slots, wherein M1 and M2 are integers which are greater than or equal to 0, and L2 is an integer which is greater than or equal to 1; the duration of the second time interval is on the second frequency domain resource

A monitoring period of, or

A monitoring period of, or

One monitoring period, or NxL 1 x 2^M2-M1A time slot, or

A time slot, or

And a time slot.

In one possible implementation, the time unit is a monitoring opportunity; the receiving unit is further configured to receive second configuration information sent by a network device before receiving the power consumption saving signal sent by the network device, where the second configuration information includes a reference subcarrier interval and a reference monitoring period of the power consumption saving signal;

the processing unit is specifically configured to: determining the duration of the first time period according to the reference subcarrier interval, the subcarrier interval configured by the first frequency domain resource, the reference monitoring period, the monitoring period of the communication device on the first frequency domain resource, and the N time units; and determining the duration of the second time interval according to the reference subcarrier interval, the subcarrier interval configured by the second frequency domain resource, the reference monitoring period, the monitoring period of the communication equipment on the second frequency domain resource and the N time units.

In one possible implementation, the reference subcarrier spacing is 15 x 2^M0kHz, a reference monitoring period is L0 time slots, M0 is an integer greater than or equal to 0, and L0 is an integer greater than or equal to 1; subcarrier spacing 15 x 2 of the first frequency domain resource configuration^M1kHz, subcarrier spacing of said second frequency domain resource configuration 15 x 2^M2kHz, wherein the monitoring period of the communication equipment on the first frequency domain resource is L1 time slots, the monitoring period of the communication equipment on the second frequency domain resource is L2 time slots, wherein M1 and M2 are integers which are greater than or equal to 0, and L1 and L2 are integers which are greater than or equal to 1;

the duration of the first time interval is on the first frequency domain resource

A monitoring period of, or

A monitoring period of, or

One monitoring period, or NxL 0 x 2^M1-M0A time slot, or

A time slot, or

A time slot; the duration of the second time interval is on the second frequency domain resource

A monitoring period of, or

A monitoring period of, or

One monitoring period, or NxL 0 x 2^M2-M0A time slot, or

A time slot, or

And a time slot.

In one possible implementation manner, the time unit is a C-DRX cycle, the C-DRX cycle of the first frequency domain resource configuration is K1 absolute time units, and K1 is an integer greater than or equal to 1; the duration of the first period is N C-DRX cycles, or N x K1 absolute time units, on the first frequency domain resource; the duration of the second period is determined according to the C-DRX cycle of the communication device configured on the first frequency domain resource, the C-DRX cycle of the communication device configured on the second frequency domain resource and the N time units.

In one possible implementation, the C-DRX cycle of the second frequency domain resource configuration is K2 absolute time units, and K2 is an integer greater than or equal to 1; the duration of the second time interval is N x K1/K2C-DRX cycles or N x K1 absolute time units on the second frequency domain resource.

In one possible implementation, the time unit is a C-DRX cycle; the receiving unit is further configured to receive third configuration information sent by a network device before receiving the power consumption saving signal sent by the network device, where the third configuration information includes that a reference C-DRX cycle of the power consumption saving signal is K0 absolute time units;

the processing unit is specifically configured to: determining a duration of the first period in accordance with the reference C-DRX cycle, the C-DRX cycle at which the communication device is configured at the first frequency domain resource, and the N time units; determining the duration of the second period according to the reference C-DRX cycle, the C-DRX cycle that the communication device is configured at the second frequency domain resource and the N time units.

In one possible implementation manner, the C-DRX cycle of the first frequency domain resource configuration is K1 absolute time units, the C-DRX cycle of the second frequency domain resource configuration is K2 absolute time units, and K1 and K2 are integers greater than or equal to 1; the duration of the first time interval is N x K0/K1C-DRX cycles or N x K0 absolute time units on the first frequency domain resource; the duration of the second time interval is N x K0/K2C-DRX cycles or N x K0 absolute time units on the second frequency domain resource.

In a possible implementation manner, the receiving unit receives, on the first frequency domain resource, a power consumption saving signal sent by the network device.

In a possible implementation manner, the first frequency domain resource is a first carrier, and the second frequency domain resource is a second carrier; or, the first frequency-domain resource is a first bandwidth portion BWP, and the second frequency-domain resource is a second BWP.

In one possible implementation, the first signal is one or more of the following signals: PDCCH, CSI-RS, SSB.

In a fourth aspect, an embodiment of the present application further provides a communication device, which includes a sending unit and a processing unit.

The sending unit is configured to send a power consumption saving signal to a terminal, where the power consumption saving signal indicates N time units, where N is an integer greater than 0, and is used to indicate a state of the terminal in a first time period corresponding to the N time units on a first frequency domain resource and a state in a second time period corresponding to the N time units on a second frequency domain resource, where the state is a sleep state or an awake state, the sleep state indicates that the terminal does not monitor a first signal, and the awake state indicates that the terminal monitors the first signal according to a configuration parameter;

and the processing unit is used for sending the first signal or not sending the first signal to the terminal through the sending unit according to the state.

In a possible implementation manner, the time unit is a time slot, and the duration of the first period is N time slots of the first frequency domain resource; and the duration of the second time interval is determined according to the subcarrier interval configured by the first frequency domain resource, the subcarrier interval configured by the second frequency domain resource and the N time units.

In a possible implementation manner, the subcarrier spacing of the first frequency domain resource configuration is 15 × 2^M1kHz, subcarrier spacing of said second frequency domain resource configuration 15 x 2^M2kHz, wherein M1 and M2 are integers greater than or equal to 0; the duration of the second time interval is N x 2 of the second frequency domain resource^M2-M1A time slot, or

A time slot, or

And a time slot.

In one possible implementation, the time unit is a time slot; the sending unit is further configured to send first configuration information to a terminal before sending a power saving signal to the terminal, where the first configuration information includes a reference subcarrier interval of the power saving signal;

the duration of the first time interval is determined according to the reference subcarrier interval, the subcarrier interval of the first frequency domain resource allocation and the N time units; and the duration of the second time interval is determined according to the reference subcarrier interval, the subcarrier interval configured by the second frequency domain resource and the N time units.

In one possible implementation, the reference subcarrier spacing is 15 x 2^M0kHz, subcarrier spacing of said first frequency domain resource configuration 15 x 2^M1kHz, subcarrier spacing of said second frequency domain resource configuration 15 x 2^M2kHz; the duration of the first time interval is N x 2 of the first frequency domain resource^M1-M0A time slot, or

A time slot, or

A time slot; the duration of the second time interval is N x 2 of the second frequency domain resource^M2-M0A time slot, or

A time slot, or

And a time slot.

In one possible implementation, the time unit is a monitoring opportunity; the duration of the first period is N monitoring cycles on the first frequency domain resource, or N × L1 time slots, where L denotes that the monitoring cycle of the terminal on the first frequency domain resource is L1 time slots, and L1 is an integer greater than or equal to 1; and the duration of the second time interval is determined according to the subcarrier interval configured by the first frequency domain resource, the subcarrier interval configured by the second frequency domain resource, the monitoring period of the terminal on the first frequency domain resource, the monitoring period of the terminal on the second frequency domain resource and the N time units.

In a possible implementation manner, the subcarrier spacing of the first frequency domain resource configuration is 15 × 2^M1kHz, subcarrier spacing of said second frequency domain resource configuration 15 x 2^M2kHz, wherein the monitoring period of the terminal on the second frequency domain resource is L2 time slots, M1 and M2 are integers which are greater than or equal to 0, and L2 is an integer which is greater than or equal to 1; the duration of the second time interval is on the second frequency domain resource

A monitoring period of, or

A monitoring period of, or

One monitoring period, or NxL 1 x 2^M2-M1A time slot, or

A time slot, or

And a time slot.

In one possible implementation, the time unit is a monitoring opportunity; the sending unit is further configured to send second configuration information to the terminal before sending a power consumption saving signal to the terminal, where the second configuration information includes a reference subcarrier interval and a reference monitoring period of the power consumption saving signal;

the duration of the first time interval is determined according to the reference subcarrier interval, the subcarrier interval configured by the first frequency domain resource, the reference monitoring period, the monitoring period of the terminal on the first frequency domain resource, and the N time units; and the duration of the second time interval is determined according to the reference subcarrier interval, the subcarrier interval configured by the second frequency domain resource, the reference monitoring period, the monitoring period of the terminal on the second frequency domain resource and the N time units.

In one possible implementation, the reference subcarrier spacing is 15 x 2^M0kHz, a reference monitoring period is L0 time slots, M0 is an integer greater than or equal to 0, and L0 is an integer greater than or equal to 1; subcarrier spacing 15 x 2 of the first frequency domain resource configuration^M1kHz, subcarrier spacing of said second frequency domain resource configuration 15 x 2^M2kHz, the monitoring period of the terminal on the first frequency domain resource is L1 time slots, the monitoring period of the terminal on the second frequency domain resource is L2 time slots, wherein M1 and M2 are integers which are greater than or equal to 0, and L1 and L2 are integers which are greater than or equal to 1;

the duration of the first time interval is on the first frequency domain resource

A monitoring period of, or

A monitoring period of, or

One monitoring period, or NxL 0 x 2^M1-M0A time slot, or

A time slot, or

A time slot; the duration of the second time interval is on the second frequency domain resource

A monitoring period of, or

A monitoring period of, or

One monitoring period, or NxL 0 x 2^M2-M0A time slot, or

A time slot, or

And a time slot.

In one possible implementation manner, the time unit is a C-DRX cycle, the C-DRX cycle of the first frequency domain resource configuration is K1 absolute time units, and K1 is an integer greater than or equal to 1; the duration of the first period is N C-DRX cycles, or N x K1 absolute time units, on the first frequency domain resource; the duration of the second period is determined according to the C-DRX cycle configured by the terminal on the first frequency domain resource, the C-DRX cycle configured by the terminal on the second frequency domain resource and the N time units.

In one possible implementation, the C-DRX cycle of the second frequency domain resource configuration is K2 absolute time units, and K2 is an integer greater than or equal to 1; the duration of the second time interval is N x K1/K2C-DRX cycles or N x K1 absolute time units on the second frequency domain resource.

In a possible implementation manner, the sending unit is further configured to send third configuration information to the terminal, where the third configuration information includes that a reference C-DRX cycle of the power consumption saving signal is K0 absolute time units;

the duration of the first period is determined according to the reference C-DRX cycle, the C-DRX cycle configured by the terminal in the first frequency domain resource and the N time units; and the duration of the second period is determined according to the reference C-DRX cycle, the C-DRX cycle configured by the terminal in the second frequency domain resource and the N time units.

In one possible implementation manner, the C-DRX cycle of the first frequency domain resource configuration is K1 absolute time units, the C-DRX cycle of the second frequency domain resource configuration is K2 absolute time units, and K1 and K2 are integers greater than or equal to 1; the duration of the first time interval is N x K0/K1C-DRX cycles or N x K0 absolute time units on the first frequency domain resource; the duration of the second time interval is N x K0/K2C-DRX cycles or N x K0 absolute time units on the second frequency domain resource.

In one possible implementation, the sending unit sends a power saving signal to the terminal on the first frequency domain resource.

In a possible implementation manner, the first frequency domain resource is a first carrier, and the second frequency domain resource is a second carrier; or, the first frequency-domain resource is a first bandwidth portion BWP, and the second frequency-domain resource is a second BWP.

In one possible implementation, the first signal is one or more of the following signals: PDCCH, CSI-RS, SSB.

In a fifth aspect, an embodiment of the present application provides a communication device, which includes a processor and a communication interface, where the processor is coupled with a memory and the communication interface;

the processor is used for calling the program stored in the memory and executing the following steps:

receiving a power consumption saving signal sent by network equipment through the communication interface, wherein the power consumption saving signal indicates N time units, and N is an integer greater than 0;

determining, according to the power saving signal, a state of the communication device in a first time period corresponding to the N time units on a first frequency domain resource and a state in a second time period corresponding to the N time units on a second frequency domain resource;

the state is a sleep state or an awake state, the sleep state indicates that the communication device does not monitor the first signal, and the awake state indicates that the communication device monitors the first signal according to the configuration parameter.

In a possible implementation manner, the time unit is a time slot, and the duration of the first period is N time slots of the first frequency domain resource; and the duration of the second time interval is determined according to the subcarrier interval configured by the first frequency domain resource, the subcarrier interval configured by the second frequency domain resource and the N time units.

In a possible implementation manner, the subcarrier spacing of the first frequency domain resource configuration is 15 × 2^M1kHz, subcarrier spacing of said second frequency domain resource configuration 15 x 2^M2kHz, wherein M1 and M2 are integers greater than or equal to 0; the duration of the second time interval is N x 2 of the second frequency domain resource^M2-M1A time slot, or

A time slot, or

And a time slot.

In one possible implementation, the time unit is a time slot; the processor, prior to receiving the power saving signal sent by the network device through the communication interface, is further configured to: receiving, by the communication interface, first configuration information sent by the network device, where the first configuration information includes a reference subcarrier spacing of the power saving signal;

the processor is specifically configured to: determining the duration of the first time period according to the reference subcarrier interval, the subcarrier interval of the first frequency domain resource allocation and the N time units; and determining the duration of the second time period according to the reference subcarrier interval, the subcarrier interval configured by the second frequency domain resource and the N time units.

In one possible implementation, the reference subcarrier spacing is 15 x 2^M0kHz, subcarrier spacing of said first frequency domain resource configuration 15 x 2^M1kHz, subcarrier spacing of said second frequency domain resource configuration 15 x 2^M2kHz; the duration of the first time interval is N x 2 of the first frequency domain resource^M1-M0A time slot, or

A time slot, or

A time slot; the duration of the second time interval is N x 2 of the second frequency domain resource^M2-M0A time slot, or

A time slot, or

And a time slot.

In one possible implementation, the time unit is a monitoring opportunity; the duration of the first period is N monitoring cycles on the first frequency domain resource, or N × L1 time slots, where L denotes that the monitoring cycle on the first frequency domain resource of the communication device is L1 time slots, and L1 is an integer greater than or equal to 1; the duration of the second time interval is determined according to the subcarrier interval configured by the first frequency domain resource, the subcarrier interval configured by the second frequency domain resource, the monitoring period of the communication device on the first frequency domain resource, the monitoring period of the communication device on the second frequency domain resource, and the N time units.

In a possible implementation manner, the subcarrier spacing of the first frequency domain resource configuration is 15 × 2^M1kHz, subcarrier spacing of said second frequency domain resource configuration 15 x 2^M2kHz, a monitoring period of the communication device on the second frequency domain resource is L2 time slots, wherein M1 and M2 are integers which are greater than or equal to 0, and L2 is an integer which is greater than or equal to 1; the duration of the second time interval is on the second frequency domain resource

A monitoring period of, or

A monitoring period of, or

One monitoring period, or NxL 1 x 2^M2-M1A time slot, or

A time slot, or

And a time slot.

In one possible implementation, the time unit is a monitoring opportunity; the processor, prior to receiving the power saving signal sent by the network device through the communication interface, is further configured to: receiving second configuration information sent by the network device through the communication interface, where the second configuration information includes a reference subcarrier interval and a reference monitoring period of the power consumption saving signal;

the processor is specifically configured to: determining the duration of the first time period according to the reference subcarrier interval, the subcarrier interval configured by the first frequency domain resource, the reference monitoring period, the monitoring period of the communication device on the first frequency domain resource, and the N time units; and determining the duration of the second time interval according to the reference subcarrier interval, the subcarrier interval configured by the second frequency domain resource, the reference monitoring period, the monitoring period of the communication equipment on the second frequency domain resource and the N time units.

In one possible implementation, the reference subcarrier spacing is 15 x 2^M0kHz, a reference monitoring period is L0 time slots, M0 is an integer greater than or equal to 0, and L0 is an integer greater than or equal to 1; subcarrier spacing 15 x 2 of the first frequency domain resource configuration^M1kHz, subcarrier spacing of said second frequency domain resource configuration 15 x 2^M2kHz, wherein the monitoring period of the communication equipment on the first frequency domain resource is L1 time slots, the monitoring period of the communication equipment on the second frequency domain resource is L2 time slots, wherein M1 and M2 are integers which are greater than or equal to 0, and L1 and L2 are integers which are greater than or equal to 1;

the duration of the first time interval is on the first frequency domain resource

A monitoring period of, or

A monitoring period of, or

One monitoring period, or NxL 0 x 2^M1-M0A time slot, or

A time slot, or

A time slot; the duration of the second time interval is on the second frequency domain resource

A monitoring period of, or

A monitoring period of, or

One monitoring period, or NxL 0 x 2^M2-M0A time slot, or

A time slot, or

And a time slot.

In one possible implementation manner, the time unit is a C-DRX cycle, the C-DRX cycle of the first frequency domain resource configuration is K1 absolute time units, and K1 is an integer greater than or equal to 1; the duration of the first period is N C-DRX cycles, or N x K1 absolute time units, on the first frequency domain resource; the duration of the second period is determined according to the C-DRX cycle of the communication device configured on the first frequency domain resource, the C-DRX cycle of the communication device configured on the second frequency domain resource and the N time units.

In one possible implementation, the C-DRX cycle of the second frequency domain resource configuration is K2 absolute time units, and K2 is an integer greater than or equal to 1; the duration of the second time interval is N x K1/K2C-DRX cycles or N x K1 absolute time units on the second frequency domain resource.

In one possible implementation, the time unit is a C-DRX cycle; the processor, prior to receiving the power saving signal sent by the network device through the communication interface, is further configured to: receiving, by the communication interface, third configuration information sent by the network device, where the third configuration information includes that a reference C-DRX cycle of the power saving signal is K0 absolute time units;

the processor is specifically configured to: determining a duration of the first period in accordance with the reference C-DRX cycle, the C-DRX cycle at which the communication device is configured at the first frequency domain resource, and the N time units; determining the duration of the second period according to the reference C-DRX cycle, the C-DRX cycle that the communication device is configured at the second frequency domain resource and the N time units.

In one possible implementation manner, the C-DRX cycle of the first frequency domain resource configuration is K1 absolute time units, the C-DRX cycle of the second frequency domain resource configuration is K2 absolute time units, and K1 and K2 are integers greater than or equal to 1; the duration of the first time interval is N x K0/K1C-DRX cycles or N x K0 absolute time units on the first frequency domain resource; the duration of the second time interval is N x K0/K2C-DRX cycles or N x K0 absolute time units on the second frequency domain resource.

In one possible implementation, the communication device receives, through the communication interface, a power saving signal sent by the network device on the first frequency domain resource.

In a possible implementation manner, the first frequency domain resource is a first carrier, and the second frequency domain resource is a second carrier; or, the first frequency-domain resource is a first bandwidth portion BWP, and the second frequency-domain resource is a second BWP.

In one possible implementation, the first signal is one or more of the following signals: PDCCH, CSI-RS, SSB.

The communication device may be a chip, and the memory may be an on-chip memory or an off-chip memory.

In a sixth aspect, an embodiment of the present application provides a communication device, a processor and a communication interface, where the processor is coupled with a memory and the communication interface;

the processor is used for calling the program stored in the memory and executing the following steps:

sending a power consumption saving signal to a terminal through the communication interface, wherein the power consumption saving signal indicates N time units, N is an integer greater than 0, and is used for indicating the state of the terminal in a first time period corresponding to the N time units on a first frequency domain resource and a second time period corresponding to the N time units on a second frequency domain resource, the state is a sleep state or an awakening state, the sleep state indicates that the terminal does not monitor a first signal, and the awakening state monitors the first signal according to configuration parameters; and sending the first signal or not sending the first signal to the terminal through the communication interface according to the state.

In a possible implementation manner, the time unit is a time slot, and the duration of the first period is N time slots of the first frequency domain resource; and the duration of the second time interval is determined according to the subcarrier interval configured by the first frequency domain resource, the subcarrier interval configured by the second frequency domain resource and the N time units.

In a possible implementation manner, the subcarrier spacing of the first frequency domain resource configuration is 15 × 2^M1kHz, subcarrier spacing of said second frequency domain resource configuration 15 x 2^M2kHz, wherein M1 and M2 are integers greater than or equal to 0; the duration of the second time interval is N x 2 of the second frequency domain resource^M2-M1A time slot, or

A time slot, or

And a time slot.

In one possible implementation, the time unit is a time slot; the processor, prior to sending a power saving signal to a terminal over the communication interface, is further to: sending first configuration information to the terminal through the communication interface, the first configuration information including a reference subcarrier spacing of the power saving signal;

the duration of the first time interval is determined according to the reference subcarrier interval, the subcarrier interval of the first frequency domain resource allocation and the N time units; and the duration of the second time interval is determined according to the reference subcarrier interval, the subcarrier interval configured by the second frequency domain resource and the N time units.

In one possible implementation, the reference subcarrier spacing is 15 x 2^M0kHz, subcarrier spacing of said first frequency domain resource configuration 15 x 2^M1kHz, subcarrier spacing of said second frequency domain resource configuration 15 x 2^M2kHz; the duration of the first time interval is N x 2 of the first frequency domain resource^M1-M0A time slot, or

A time slot, or

A time slot; the duration of the second time interval is N x 2 of the second frequency domain resource^M2-M0A time slot, or

A time slot, or

And a time slot.

In one possible implementation, the time unit is a monitoring opportunity; the duration of the first period is N monitoring cycles on the first frequency domain resource, or N × L1 time slots, where L denotes that the monitoring cycle of the terminal on the first frequency domain resource is L1 time slots, and L1 is an integer greater than or equal to 1; and the duration of the second time interval is determined according to the subcarrier interval configured by the first frequency domain resource, the subcarrier interval configured by the second frequency domain resource, the monitoring period of the terminal on the first frequency domain resource, the monitoring period of the terminal on the second frequency domain resource and the N time units.

In a possible implementation manner, the subcarrier spacing of the first frequency domain resource configuration is 15 × 2^M1kHz, subcarrier spacing of said second frequency domain resource configuration 15 x 2^M2kHz, wherein the monitoring period of the terminal on the second frequency domain resource is L2 time slots, M1 and M2 are integers which are greater than or equal to 0, and L2 is an integer which is greater than or equal to 1; the duration of the second time interval isOn the second frequency domain resource

A monitoring period of, or

A monitoring period of, or

One monitoring period, or NxL 1 x 2^M2-M1A time slot, or

A time slot, or

And a time slot.

In one possible implementation, the time unit is a monitoring opportunity; the processor, prior to sending a power saving signal to a terminal over the communication interface, is further to: sending second configuration information to the terminal through the communication interface, wherein the second configuration information comprises a reference subcarrier interval and a reference monitoring period of the power consumption saving signal;

the duration of the first time interval is determined according to the reference subcarrier interval, the subcarrier interval configured by the first frequency domain resource, the reference monitoring period, the monitoring period of the terminal on the first frequency domain resource, and the N time units; and the duration of the second time interval is determined according to the reference subcarrier interval, the subcarrier interval configured by the second frequency domain resource, the reference monitoring period, the monitoring period of the terminal on the second frequency domain resource and the N time units.

In one possible implementation, the reference subcarrier spacing is 15 x 2^M0kHz, a reference monitoring period is L0 time slots, M0 is an integer greater than or equal to 0, and L0 is an integer greater than or equal to 1; subcarrier spacing 15 x 2 of the first frequency domain resource configuration^M1kHz, subcarrier spacing of the second frequency domain resource configuration15*2^M2kHz, the monitoring period of the terminal on the first frequency domain resource is L1 time slots, the monitoring period of the terminal on the second frequency domain resource is L2 time slots, wherein M1 and M2 are integers which are greater than or equal to 0, and L1 and L2 are integers which are greater than or equal to 1;

the duration of the first time interval is on the first frequency domain resource

A monitoring period of, or

A monitoring period of, or

One monitoring period, or NxL 0 x 2^M1-M0A time slot, or

A time slot, or

A time slot; the duration of the second time interval is on the second frequency domain resource

A monitoring period of, orA monitoring period of, or

One monitoring period, or NxL 0 x 2^M2-M0A time slot, or

A time slot, or

And a time slot.

In one possible implementation manner, the time unit is a C-DRX cycle, the C-DRX cycle of the first frequency domain resource configuration is K1 absolute time units, and K1 is an integer greater than or equal to 1; the duration of the first period is N C-DRX cycles, or N x K1 absolute time units, on the first frequency domain resource; the duration of the second period is determined according to the C-DRX cycle configured by the terminal on the first frequency domain resource, the C-DRX cycle configured by the terminal on the second frequency domain resource and the N time units.

In one possible implementation, the C-DRX cycle of the second frequency domain resource configuration is K2 absolute time units, and K2 is an integer greater than or equal to 1; the duration of the second time interval is N x K1/K2C-DRX cycles or N x K1 absolute time units on the second frequency domain resource.

In one possible implementation, the processor is further configured to: sending third configuration information to the terminal through the communication interface, the third configuration information including that a reference C-DRX cycle of the power consumption saving signal is K0 absolute time units;

the duration of the first period is determined according to the reference C-DRX cycle, the C-DRX cycle configured by the terminal in the first frequency domain resource and the N time units; and the duration of the second period is determined according to the reference C-DRX cycle, the C-DRX cycle configured by the terminal in the second frequency domain resource and the N time units.

In one possible implementation manner, the C-DRX cycle of the first frequency domain resource configuration is K1 absolute time units, the C-DRX cycle of the second frequency domain resource configuration is K2 absolute time units, and K1 and K2 are integers greater than or equal to 1; the duration of the first time interval is N x K0/K1C-DRX cycles or N x K0 absolute time units on the first frequency domain resource; the duration of the second time interval is N x K0/K2C-DRX cycles or N x K0 absolute time units on the second frequency domain resource.

In one possible implementation, the communication device sends a power saving signal to the terminal on the first frequency domain resource through the communication interface.

In a possible implementation manner, the first frequency domain resource is a first carrier, and the second frequency domain resource is a second carrier; or, the first frequency-domain resource is a first bandwidth portion BWP, and the second frequency-domain resource is a second BWP.

In one possible implementation, the first signal is one or more of the following signals: PDCCH, CSI-RS, SSB.

The communication device may be a chip, and the memory may be an on-chip memory or an off-chip memory.

In a seventh aspect, this application provides a computer-readable storage medium, which stores computer instructions, and when the instructions are executed on a computer, the instructions cause the computer to perform the functions performed by the terminal in the method in any one of the first aspect or the second aspect, or cause the computer to perform the functions performed by the network device in the method in any one of the first aspect or the second aspect.

In an eighth aspect, embodiments of the present application provide a computer program product comprising instructions, which when run on a computer, cause the computer to perform functions performed by a terminal in the method according to any one of the first aspect or the second aspect, or cause the computer to perform functions performed by a network device in the method according to any one of the first aspect or the second aspect.

In a ninth aspect, the present application provides a chip, where the chip is connected to a memory, and is configured to read and execute a software program stored in the memory, so as to implement a function performed by a terminal in any one of the methods in the first aspect or the second aspect, or implement a function performed by a network device in any one of the methods in the first aspect or the second aspect.

Drawings

Fig. 1 is a schematic diagram of time slots on different frequency domain resources according to an embodiment of the present application;

fig. 2 is an application scenario provided in an embodiment of the present application;

fig. 3 is a schematic flowchart of a communication method according to an embodiment of the present application;

fig. 4 to 13 are schematic diagrams of a first period and a second period provided in an embodiment of the present application;

fig. 14 is a schematic diagram of C-DRX provided in the embodiment of the present application;

FIG. 15 is a schematic diagram of a first time period and a second time period provided by an embodiment of the present application;

fig. 16 to 18 are schematic diagrams of the start time of the first time interval or the second time interval according to the embodiment of the present application;

fig. 19 is a schematic structural diagram of a terminal according to an embodiment of the present application;

fig. 20 is a schematic structural diagram of a network device according to an embodiment of the present application;

fig. 21 is a second schematic structural diagram of a terminal according to an embodiment of the present application;

fig. 22 is a second schematic structural diagram of a network device according to an embodiment of the present application.

Detailed Description

In order to make the objects, technical solutions and advantages of the present application more clear, the present application will be further described in detail with reference to the accompanying drawings.

First, the concept related to the present application will be explained.

-Carrier Aggregation (CA)

In an initial stage of a Long Term Evolution (LTE) standard, a maximum bandwidth of 20MHz is specified for one carrier. In a later standardization process, LTE is further improved and is referred to as LTE-a. In order to meet the requirements of LTE-A (Long term evolution-advanced) downlink peak speed of 1Gbps and uplink peak speed of 500Mbps, a transmission bandwidth of 100MHz at most needs to be provided. However, due to the scarcity of large-bandwidth continuous spectrum, LTE-a proposes a solution for carrier aggregation. Carrier aggregation is the aggregation of 2 or more Component Carriers (CCs) together to support a larger transmission bandwidth. 1 CC can be generally equated with 1 cell, and the maximum bandwidth of each CC is 20 MHz.

A terminal may configure multiple CCs, where one CC is called a primary cell (PCell), and is a cell where the terminal initially accesses, or is a cell where Radio Resource Control (RRC) connection is reestablished, or is a primary cell designated in a handover (handover) process. The PCell is responsible for RRC communication with the terminal, and a Physical Uplink Control Channel (PUCCH) is transmitted only on the PCell. The remaining CCs, referred to as secondary cells (scells), are added at the time of RRC reconfiguration for providing additional radio resources.

In a New Radio (NR), the CA technology is still used, where uplink and downlink respectively support 16 CCs at most. Meanwhile, when the base station bandwidth is large and the terminal capability is insufficient and cannot support the large bandwidth through a single carrier, the terminal can support the large bandwidth through an intra-band continuous ca (intra-band connectivity ca) mode. For example, when the bandwidth of the base station is 400MHz and the maximum continuous bandwidth supported by the terminal is 100MHz, the terminal may regard the bandwidth of the base station as an aggregation of 4 bandwidths of 100MHz, and communicate with the base station in a CA manner.

-bandwidth part (BWP)

The NR introduces the concept of BWP, i.e. supporting transmission between the network device and the UE with a part of bandwidth occupied. Since the system bandwidth of 5G (referring to the bandwidth of one carrier, the bandwidth of each CC in a corresponding CA or Dual Connectivity (DC) scenario) may be 200MHz or 400MHz, and some terminals do not support such a large bandwidth, the network device may configure BWP (portion of the system bandwidth), for example, 20MHz, to the terminals, and the terminals may communicate with the network device at the 20 MHz.

BWPs may be divided into downlink BWPs (DL BWPs) and uplink BWPs (UL BWPs), where a network device may configure multiple DL BWPs and/or multiple UL BWPs for a terminal and activate at least one DL BWP and at least one UL BWP, and a UE receives a downlink signal sent by the network device on the activated DL BWP, including but not limited to: downlink control signaling, downlink data, and the like; the terminal transmits uplink signals on the activated UL BWP, including but not limited to: uplink control signaling, uplink data, uplink Scheduling Request (SR), uplink Sounding Reference Signal (SRs), Channel State Information (CSI), Channel Quality Indicator (CQI) feedback, and the like.

Parameter sets (numerology)

In the standardization of NR, the concept of numerology is introduced. A plurality of numerologies are supported in the NR, each numerology being determined by a sub-carrier spacing (SCS) and a Cyclic Prefix (CP). The different numerologies may be time or frequency multiplexed, i.e., different numerologies may be used on different time or frequency domains.

The numerology of different CCs or BWPs may be different. Different numerology results in different slot lengths. As shown in fig. 1 below, for example, when the subcarrier spacing of CC1 is 30kHz and the subcarrier spacing of CC2 is 15kHz, the length of one slot on CC2 is equal to the length of two slots on CC 1.

-power saving signal (power saving signal)

In order to save power consumption of the terminal, the network device may indicate whether the terminal monitors a Physical Downlink Control Channel (PDCCH) through a power saving signal (power saving signal). The terminal monitors the PDCCH according to the power consumption saving signal in a time period when the network equipment is likely to schedule the terminal, namely, the terminal is in an awakening state; and the network device does not monitor the PDCCH in a period when the terminal is not scheduled, namely, the network device is in a sleep state. The power saving signal has the following three implementation modes:

the wake-up signal is used for informing the terminal when to enter the wake-up state when the terminal is in a sleep state (i.e., not monitoring the PDCCH, and/or not receiving the downlink reference signal, and/or not performing measurement), and monitoring the PDCCH, and/or receiving the downlink reference signal, and/or performing measurement according to the configuration parameters.

The second is a sleep signal, which is used to inform the terminal when the terminal enters the sleep state, does not monitor the PDCCH, and/or does not receive the downlink reference signal, and/or does not perform measurement when the terminal is in the awake state (i.e. monitors the PDCCH according to the configuration parameters, and/or receives the downlink reference signal, and/or performs measurement).

Thirdly, a general power consumption saving signal contains indication information, and further indicates whether the terminal needs to be in an awakening state or a sleeping state in the next period of time; and after receiving the signal, the terminal determines whether the terminal is in the awakening state or the sleeping state in the following time according to the indication information.

When the terminal is in a sleep state, the related circuit can be closed, so that the power consumption of the terminal is reduced.

If the network device determines that the PDCCH is not sent to the terminal within a certain period of time, the terminal may be notified to enter a sleep state, so as to reduce power consumption of the terminal. For example, if terminal a does not perform uplink or downlink data transmission with the network device for a period of time, the network device may infer that terminal a is more likely to have no data transmission requirement for a future period of time, and thus send a power consumption saving signal to terminal a to notify terminal a to enter a sleep state for a future period of time, so as to save power consumption. For another example, if the network device is busy currently, there is more data to be received or transmitted, and there is no time to schedule the terminal B in a future period of time, so that a power consumption saving signal is sent to the terminal B to notify the terminal B that the PDCCH does not need to be monitored in the future period of time, so as to save the power consumption of the terminal B.

The power consumption saving signal can be sent to the terminal through the DCI, so that the reliability is high, and the probability of missed detection/false detection is low; but it is necessary to modify the existing DCI format (DCI format) or introduce a new DCI format.

The power consumption saving signal can also be sent to the terminal through a sequence (sequence) or a Reference Signal (RS), the DCI format does not need to be designed, and the complexity of blind detection of the DCI by the terminal is not increased; but the reliability is low, the probability of missed detection/false detection is high, and air interface resources may be wasted.

In the CA scenario, a power saving signal may be sent separately on each CC, indicating the state of the terminal on each CC. However, in order to save signaling overhead, it is more likely that the power saving signal is transmitted on one CC, and the power saving signal transmitted on one CC may indicate the state of the terminal on multiple CCs.

Likewise, in a BWP scenario, the power saving signal may also be sent separately on each BWP, but to save signaling overhead, it is more likely to be sent on only one BWP, indicating the state of the terminal on multiple BWPs.

If the terminal determines that at a certain time point, the terminal is in a sleep state on the CC1 (or BWP1) and is in an awake state on the CC2 (or BWP2) according to the power saving signal, the related circuits of the terminal cannot be completely turned off, and the power saving effect is not significant. Ideally, the terminal is not scheduled on all CCs (or BWPs) when there is no traffic demand; when there is a service requirement, the terminal is scheduled on each CC (or BWP) simultaneously, which helps to improve data transmission efficiency and reduce transmission delay.

However, when the network device indicates the state of the terminal on the plurality of CCs (or BWPs) on one CC (or one BWP), how the terminal determines the state on the plurality of CCs (or BWPs) according to the power consumption saving signal transmitted on the one CC (or one BWP), there is no clear solution in the current standard.

In order to solve the above problem, embodiments of the present application provide a communication method and device, which are used for enabling a terminal to determine states on different frequency domain resources according to a power consumption saving signal received on one frequency domain resource. Fig. 2 exemplarily provides an application scenario of the communication method provided in the embodiment of the present application.

In this embodiment, signaling of the power consumption saving signal is not limited, and the network device may send the power consumption saving signal to the terminal through DCI, or may send the power consumption saving signal to the terminal through a sequence or a reference signal, or of course, may send the power consumption saving signal to the terminal through other signaling.

With reference to fig. 2, the network device in the embodiment of the present application may be a base station, or other network device, configured to convert a received air frame and an Internet Protocol (IP) packet to each other, and serve as a router between a wireless terminal and the rest of an access network, where the rest of the access network may include an IP network. The network device may also be used to coordinate attribute management for the air interface. In communication systems using different radio access technologies, names of devices having a base station function may be different, and for example, a base station in an LTE system is called an evolved node B (eNB), a base station in an NR system (gNB), and the like. The embodiment of the present application is not limited to this.

In conjunction with fig. 2, a terminal in the embodiments of the present application may refer to a User Equipment (UE), an access terminal, a subscriber unit, a subscriber station, a mobile station, a remote terminal, a mobile device, a user terminal device, a wireless communication device, a user agent, or a user equipment. The terminal may also be a cellular phone, a cordless phone, a Session Initiation Protocol (SIP) phone, a Wireless Local Loop (WLL) station, a Personal Digital Assistant (PDA), a handheld device with wireless communication function, a computing device or other processing device connected to a wireless modem, a vehicle-mounted device, a wearable device, a terminal device in a future 5G network or a terminal device in a future evolved Public Land Mobile Network (PLMN), and the like, which are not limited in this embodiment.

A flow diagram of a communication method provided in an embodiment of the present application may be shown in fig. 3, where the method may include the following steps:

step 301, the network device sends a power saving signal to the terminal, where the power saving signal indicates N time units, and N is greater than 0. Optionally, N is an integer greater than 0.

Step 302, after receiving the power saving signal, the terminal determines a state in a first time period corresponding to the N time units on the first frequency domain resource and a state in a second time period corresponding to the N time units on the second frequency domain resource.

The state comprises a sleep state or an awakening state, the sleep state represents that the terminal does not monitor the first signal, and the awakening state represents that the terminal monitors the first signal according to the configuration parameters.

The network device may send a sleep signal to the terminal in the awake state, and the terminal determines that the terminal enters the sleep state in the first time period on the first frequency domain resource and the second time period on the second frequency domain resource according to the sleep signal. Or, the network device may also send a wake-up signal to the terminal in the sleep state, and the terminal determines, according to the wake-up signal, that the terminal enters the wake-up state in the first time period on the first frequency domain resource and in the second time period on the second frequency domain resource. Or, the power saving signal sent by the network device to the terminal carries state indication information, and the terminal enters into which state according to the indication information; for example, if the indication information indicates that the terminal enters the awake state, the terminal enters the awake state in a first time period on the first frequency domain resource and in a second time period on the second frequency domain resource; and if the indication information indicates that the terminal enters the sleep state, the terminal enters the sleep state in a first time interval on the first frequency domain resource and in a second time interval on the second frequency domain resource.

In this embodiment of the application, the power saving signal is not limited to indicate whether the terminal monitors the PDCCH, but may also be used to indicate whether the terminal monitors other signals, for example, the first signal may also refer to CSI-RS, SSB, and the like. In the following embodiments, the first signal is described in detail as an example of a PDCCH, and it should be understood that the PDCCH in the following embodiments may be replaced by other signals such as CSI-RS and SSB.

The frequency domain resources may be CCs, that is, the first frequency domain resource is a first CC, and the second frequency domain resource is a second CC. Further, the first CC may be a primary CC, and the first CC may be a secondary CC.

The frequency-domain resource may also be BWP, that is, the first frequency-domain resource is a first BWP, and the second frequency-domain resource is a second BWP. Further, the first BWP may be a primary BWP and the second BWP may be a secondary BWP. Or the first BWP may be a primary on-CC BWP and the second BWP may be a secondary on-CC BWP. BWP may also be referred to as carrier bandwidth part (carrier bandwidth part), sub-band (subband) bandwidth, narrowband (narrowband) bandwidth, or other names, but is not limited thereto.

In a possible implementation, the N time units indicated by the power saving signal may be N time slots, or N monitoring occasions, or N C-DRX cycles. How to determine the first period and the second period is described below for these three cases, respectively.

Embodiment and N time slots

As mentioned above, a time slot is not an absolute time unit, and the absolute time length of one time slot is related to the size of the subcarrier spacing. Therefore, the network device needs to consider the size of the subcarrier spacing when determining the size of N.

In a possible implementation manner, the subcarrier interval configured by the first frequency domain resource is used as the reference subcarrier interval, so that the N time slots indicated by the network device are the N time slots on the first frequency domain resource. Therefore, the terminal may directly determine the first period as N slots on the first frequency domain resource.

The terminal may determine the duration of the second period according to the subcarrier spacing of the first frequency domain resource configuration, the subcarrier spacing of the second frequency domain resource configuration, and N.

Optionally, the terminal may calculate the duration of the second period according to the subcarrier interval of the first frequency-domain resource, the subcarrier interval of the second frequency-domain resource, and N. For example, if the subcarrier spacing of the first frequency domain resource allocation is 15 × 2^M1kHz, subcarrier spacing of the second frequency domain resource allocation is 15 x 2^M2kHz, M1 and M2 are integers of 0 or more; the terminal determines the duration of the second time interval to be N x 2 on the second frequency domain resource^M2-M1And a time slot.

For example, the subcarrier spacing of CC1 is 15kHz, i.e., M1 is 0, the subcarrier spacing of CC2 is 30kHz, i.e., M2 is 1, and the terminal monitors the PDCCH once per slot on both CC1 and CC 2. The power saving signal indicates that the terminal does not receive the PDCCH in the next 4 slots, the terminal determines the duration of the first period to be 4 slots on CC1, and determines the duration of the second period to be N × 2 on CC2^M2-M1＝4*2^1-0As shown in fig. 4, the terminal no longer monitors the PDCCH on CC1 for the first period and on CC2 for the second period.

For another example, the subcarrier spacing of CC1 is 30kHz, that is, M1 is 1, and the subcarrier spacing of CC2 is 15kHz, that is, M2 is 0, and the terminal monitors the PDCCH once per slot on both CC1 and CC 2.The power saving signal indicates that the terminal does not receive the PDCCH in the next 4 slots, i.e., enters a sleep state, the terminal determines that the duration of the first period is 4 slots on CC1, and the duration of the second period is N × 2 on CC2^M2-M1＝4*2^0-12 slots as shown in fig. 5.

In the above embodiment, if M2 is greater than or equal to M1, the second time interval is an integer number of time slots; if M2< M1, the second time period is a non-integer number of time slots. Since the non-integer number of slots increases the complexity of the terminal implementation, the network device may use a smaller subcarrier spacing as the reference subcarrier spacing, that is, use the resource frequency domain with a small subcarrier spacing as the first frequency domain resource, so that M2 is greater than or equal to M1, and the second period is guaranteed to be an integer number of slots.

In another design, the size of M1 and M2 may not be limited, and the terminal may add the rounding operation when calculating the second time interval, that is, the duration of the second time interval is the second frequency domain resource

A time slot, or

And time slots such that the duration of the second period is an integer number of time slots.

For example, the subcarrier spacing of CC1 is 30kHz, i.e., M1-1, and the subcarrier spacing of CC2 is 15kHz, i.e., M2-0, and the terminal monitors the PDCCH once per slot on both CC1 and CC 2. The power saving signal indicates that the terminal does not receive the PDCCH in the following 5 slots, i.e., enters a sleep state, the terminal determines that the duration of the first time period is 5 slots on CC1, and the duration of the second time period is 5 slots on CC2

A time slot, as shown in fig. 6; alternatively, the terminal determines the duration of the second period to be CC2

One slot as shown in fig. 7.

Or, the terminal may also report an error to the network device when determining the non-integer number of timeslots. Because the terminal does not expect the first period and/or the second period corresponding to the N time slots indicated by the network device to be the non-integer number of time slots, the terminal may not perform the operation of entering the awake state or entering the sleep state indicated by the power consumption saving signal and report an error to the network device when determining that the first period and/or the second period are the non-integer number of time slots. On the other hand, if the network device acquires that the first time period and/or the second time period that the terminal does not expect is a non-integer number of time slots according to the prearrangement or the communication with the terminal device, the network device may determine according to the subcarrier interval of the first frequency domain resource and the subcarrier interval of the second frequency domain resource before sending the power consumption saving signal, so that the first time period and the second time period are both the values of N of the integer number of time slots.

It should be appreciated that a non-integer number of time slots, while adding complexity to the terminal operation, is not realizable by the terminal. Therefore, if the first time interval and/or the second time interval are/is a non-integer number of slots, the terminal may perform the operation of sleep or wake-up according to the non-integer number of slots instead of rounding up or reporting an error.

For example, the subcarrier spacing of CC1 is 30kHz, i.e., M1-1, and the subcarrier spacing of CC2 is 15kHz, i.e., M2-0, and the terminal monitors the PDCCH once per slot on both CC1 and CC 2. The power saving signal indicates that the terminal does not receive the PDCCH in the next 5 slots, i.e., enters a sleep state, the terminal determines that the duration of the first period is 5 slots on CC1, and the duration of the second period is N × 2 on CC2^M2-M12.5 time slots as shown in fig. 8.

Optionally, the terminal may determine the duration of the second period according to the subcarrier spacing of the first frequency-domain resource, the subcarrier spacing of the second frequency-domain resource, and the N lookup table. For example, the subcarrier spacing of the first frequency domain resource configuration is 15 x 2^M1kHz, subcarrier spacing of the second frequency domain resource allocation is 15 x 2^M2kHz, a second period duration corresponding table shown in the table 1 is configured in the terminal in advance.

TABLE 1

It should be understood that the numerical values shown in table 1 are only examples and do not limit the present application.

Further, the second time length X in table 1 may be determined according to the formula in the foregoing embodiment.

In another possible implementation manner, the network device may not use the subcarrier spacing of the first frequency domain resource configuration or the subcarrier spacing of the second frequency domain resource configuration as the reference subcarrier spacing. The network device may send first configuration information to the terminal before sending the power saving signal to the terminal, the first configuration information including a reference subcarrier spacing of the power saving signal.

Correspondingly, the terminal determines the duration of the first time period according to the reference subcarrier interval, the subcarrier interval configured by the first frequency domain resource and N, and determines the duration of the second time period according to the reference subcarrier interval, the subcarrier interval configured by the second frequency domain resource and N.

Optionally, the terminal may further calculate the duration of the first time period according to the reference subcarrier interval, the subcarrier interval of the first frequency domain resource, and N, and calculate the duration of the second time period according to the reference subcarrier interval, the subcarrier interval of the second frequency domain resource, and N.

For example, if the reference subcarrier spacing is 15 x 2^M0kHz, subcarrier spacing of the first frequency domain resource allocation is 15 x 2^M1kHz, subcarrier spacing of the second frequency domain resource allocation is 15 x 2^M2kHz, M0, M1 and M2 are integers which are more than or equal to 0; the terminal determines the first period to be N x 2 on the first frequency domain resource^M1-M0Time slots, the duration of the second period is N x 2 on the second frequency domain resource^M2-M0And a time slot.

If M1 is more than or equal to M0 and M2 is more than or equal to M0, the first time interval and the second time interval are integral time slots; if M1< M0, M2< M0, the first time interval and the second time interval are non-integral number of time slots.

As previously mentioned, the terminal may not expect the first time period and/or the second time period to be a non-integer number of time slots. In some embodiments, the reference subcarrier spacing may be made smaller than or equal to the subcarrier spacing of the first frequency domain resource and the reference subcarrier spacing may be made smaller than the second frequency domain resource, i.e., M1 ≧ M0, M2 ≧ M0, thereby guaranteeing the first period and the second period as an integer number of slots.

In other embodiments, the sizes of M0, M1, and M2 may not be limited, and the terminal may add the rounding operation when calculating the first time interval and the second time interval, that is, the duration of the first time interval is the first frequency domain resource

A time slot, or

A time slot; the second time interval is longer than the second frequency domain resource

A time slot, or

And a time slot.

In some embodiments, the terminal may also report an error to the network device when the first time period and/or the second time period is determined to be a non-integer number of time slots.

On the other hand, if the network device acquires that the first time period and/or the second time period that the terminal does not expect is a non-integer number of time slots according to the prearrangement or the communication with the terminal device, the network device may determine the first time period and/or the second time period according to the reference subcarrier interval, the subcarrier interval of the first frequency domain resource and the subcarrier interval of the second frequency domain resource before sending the power consumption saving signal, so that the first time period and the second time period are both values of N of an integer number of time slots.

Of course, the terminal may also perform a sleep or wake-up operation according to a non-integer number of slots.

Optionally, the terminal may determine the duration of the first time period according to the reference subcarrier interval, the subcarrier interval of the first frequency domain resource, and the N lookup table, and determine the duration of the second time period according to the reference subcarrier interval, the subcarrier interval of the second frequency domain resource, and the N lookup table.

For example, assume that the reference subcarrier spacing is 15 x 2^M0kHz, subcarrier spacing of the first frequency domain resource allocation is 15 x 2^M1kHz, the terminal may determine the duration of the first period according to table 2.

TABLE 2

The numerical values shown in table 2 are only examples and do not limit the present application. Further, the first time length X in table 2 may be determined according to the formula in the foregoing embodiment.

The terminal determines the duration of the second period in a similar manner to the first period, which is not illustrated here.

Generally, the first time interval and the second time interval comprise time slots which are continuous time slots.

Another embodiment, N monitoring occasions

As shown in fig. 4, the monitoring period configured for the terminal is 1 slot, and the PDCCH is monitored on the first symbol of each slot, i.e. the shaded part in fig. 4, where each shaded part is referred to as a monitoring opportunity; as shown in fig. 8, each 2 slots on CC1 includes a monitoring opportunity, i.e., the monitoring period that the terminal is configured on CC1 is 2 slots, and each 4 slots on CC2 includes a monitoring opportunity, i.e., the monitoring period that the terminal is configured on CC2 is 4 slots.

Since the monitoring occasions are not absolute time units, and the lengths of the N monitoring periods corresponding to the N monitoring occasions are related to both the monitoring periods and the subcarrier intervals, the size of the monitoring periods and the subcarrier intervals need to be considered when the network device determines the size of N. If the sleep signal sent by the network equipment indicates N monitoring occasions, the N monitoring periods do not monitor the PDCCH under the condition of referring to the monitoring period and the reference subcarrier interval; if the wake-up signal sent by the network device indicates N monitoring occasions, it indicates that the terminal monitors the PDCCH in N monitoring periods according to the configuration parameters under the condition of referring to the monitoring period and the reference subcarrier interval, that is, the terminal monitors the PDCCH at the monitoring occasion of each monitoring period in the N monitoring periods.

In a possible implementation manner, the subcarrier interval configured by the first frequency domain resource may be used as a reference subcarrier interval, and the monitoring period configured by the terminal in the first frequency domain resource may be used as a reference monitoring period, so that the N monitoring occasions indicated by the network device are N monitoring occasions of the terminal on the first frequency domain resource. Therefore, the terminal may determine to monitor or not monitor the PDCCH on the N monitoring occasions on the first frequency domain resource directly according to the power consumption saving signal, that is, the first time period is N monitoring cycles on the first frequency domain resource.

The terminal may determine the second period duration according to the subcarrier interval configured by the first frequency domain resource, the monitoring period on the first frequency domain resource, the subcarrier interval configured by the second frequency domain resource, the monitoring period on the second frequency domain resource, and N.

Optionally, the terminal may further calculate the second period duration according to the subcarrier spacing of the first frequency-domain resource, the monitoring period on the first frequency-domain resource, the subcarrier spacing of the second frequency-domain resource, the monitoring period on the second frequency-domain resource, and N. For example, if the subcarrier spacing of the first frequency domain resource is 15 x 2^M1kHz, subcarrier spacing of the second frequency domain resource is 15 x 2^M2kHz, the monitoring period of the terminal on the first frequency domain resource is L1 time slots, the monitoring period on the second frequency domain resource is L2 time slots, wherein M1 and M2 are integers which are more than or equal to 0, and L1 and L2 are integers which are more than or equal to 1; the terminal determines that the duration of the second time interval is on the second frequency domain resource

And (4) monitoring a period.

For example, the subcarrier spacing of CC1 and CC2 is 15kHz, that is, M1 is M2 is 0, and the terminal monitors the PDCCH once every 2 slots on CC1 and once every 4 slots on CC 2. The power saving signal indicates that the terminal does not receive the PDCCH in the following 4 monitoring occasions, and the terminal confirmsThe duration of the first time interval is determined as 4 monitoring cycles corresponding to 4 monitoring opportunities on CC1, namely 8 time slots, and the duration of the second time interval is determined as the duration on CC2

2 monitoring periods, i.e. 8 time slots, corresponding to each monitoring opportunity, as shown in fig. 9.

For another example, the subcarrier spacing of CC1 and CC2 is 15kHz, that is, M1 is M2 is 0, and the terminal monitors the PDCCH once every 4 slots on CC1 and once every 2 slots on CC 2. The power consumption saving signal indicates that the terminal does not receive the PDCCH in the following 1 monitoring opportunity, the terminal determines that the duration of the first period is 1 monitoring cycle, i.e., 4 slots, corresponding to 1 monitoring opportunity on CC1, and determines that the duration of the second period is on CC2

2 monitoring periods, i.e. 4 time slots, corresponding to each monitoring opportunity, as shown in fig. 10.

Optionally, the terminal may further add a rounding operation when calculating the second time period, that is, the duration of the second time period is on the second frequency domain resource

A monitoring period of, or

And monitoring cycles such that the duration of the second period is an integer number of monitoring cycles.

For example, the subcarrier spacing of CC1 and CC2 is 15kHz, that is, M1 is M2 is 0, and the terminal monitors the PDCCH once every 2 slots on CC1 and once every 3 slots on CC 2. The power saving signal indicates that the terminal does not receive the PDCCH in the following 2 monitoring occasions, the terminal determines that the duration of the first time period is 2 monitoring cycles, i.e. 4 time slots, corresponding to the 2 monitoring occasions on CC1, and determines that the duration of the second time period is on CC2

2 monitoring periods corresponding to each monitoring opportunity, namely 6 time slots. As shown in fig. 11, since the monitoring periods of CC2 and CC1 are different, after receiving the power saving signal, there may be three cases for the first monitoring timing of CC2 and the first monitoring timing of CC 1: the first monitoring timing of CC2 may coincide with the first monitoring timing of CC1, shown as CC2 in the second row of fig. 10; alternatively, the first monitoring timing of CC2 is 2 slots later than the monitoring timing of CC1, shown as CC2 in the third row in fig. 11; alternatively, the first monitoring timing of CC2 is 1 slot later than the monitoring timing of CC1, shown as CC2 in the fourth row of fig. 11.

Alternatively, the terminal determines the duration of the second period to be CC2

And 1 monitoring period corresponding to each monitoring opportunity, namely 3 time slots. As shown in fig. 12, since the monitoring periods of CC2 and CC1 are different, after receiving the power saving signal, there may be three cases for the first monitoring timing of CC2 and the first monitoring timing of CC 1: the first monitoring timing of CC2 may coincide with the first monitoring timing of CC1, shown as CC2 in the second row of fig. 12; alternatively, the first monitoring opportunity of CC2 is 2 slots later than the monitoring opportunity of CC1, as shown in the third row of CC2 in fig. 12; alternatively, the first monitoring timing of CC2 is 1 slot later than the monitoring timing of CC1, shown as CC2 in the fourth row of fig. 12.

In addition, if the terminal does not expect the second time interval to be the non-integer number of monitoring cycles, an error may be reported to the network device when the non-integer number of monitoring cycles is determined. On the other hand, if the network device acquires that the first time period and/or the second time period, which are not expected by the terminal, are non-integer monitoring cycles according to the prearrangement or the communication with the terminal device, the network device may determine the first time period and/or the second time period according to the subcarrier interval and the monitoring cycle of the first frequency domain resource and the subcarrier interval and the monitoring cycle of the second frequency domain resource before sending the power consumption saving signal, so that the first time period and the second time period are both values of N of an integer number of time slots.

In the above manner in which the terminal determines the first period duration and the second period duration, the unit of the first period duration and the second period duration is taken as the monitoring period for example, however, the terminal may also determine the number of time slots included in the first period and the number of time slots included in the second period. For example, the terminal determines the duration of the first time segment to be N × L1 time slots on the first frequency domain resource, and the duration of the second time segment to be N × L1 × 2 on the second frequency domain resource^M2-M1A time slot, or

A time slot, or

And a time slot.

For example, the subcarrier spacing of CC1 and CC2 is 15kHz, that is, M1 is M2 is 0, and the terminal monitors the PDCCH once every 2 slots on CC1 and once every 3 slots on CC 2. The power saving signal indicates that the terminal does not receive the PDCCH in the next 2 monitoring occasions, and the terminal determines the duration of the first time interval to be N × L1-2 × 4 on CC1 and determines the duration of the second time interval to be N × L1 × 2 on CC2^M2-M1＝2*2*2^1-14 slots. As shown in fig. 13, since the monitoring periods of CC2 and CC1 are different, after receiving the power saving signal, there may be three cases for the first monitoring timing of CC2 and the first monitoring timing of CC 1: the first monitoring timing of CC2 may coincide with the first monitoring timing of CC1, shown as CC2 in the second row of fig. 13, and the second period comprises 2 monitoring timings; alternatively, the first monitoring timing of CC2 is 2 slots later than the monitoring timing of CC1, such as CC2 shown in the third row of fig. 13, and the second period includes 1 monitoring timing; alternatively, the first monitoring timing of CC2 is 1 slot later than the monitoring timing of CC1, shown as CC2 in the fourth row of fig. 13, and the second period encompasses 1 monitoring timing.

In the above embodiment with the time slot as the unit, when the rounding operation is not performed, if M2 ≧ M1, the second period is an integer number of time slots; if M2< M1, the second time period is a non-integer number of time slots. Since a terminal may not expect a non-integer number of slots, a smaller subcarrier spacing may be used as the reference subcarrier spacing, i.e., a resource frequency domain with a small subcarrier spacing is used as the first frequency domain resource, such that M2 ≧ M1.

It should be appreciated that a non-integer number of monitoring periods or a non-integer number of time slots, while adding complexity to terminal operation, are not realizable by the terminal. Therefore, if the first period and/or the second period is a non-integer number of monitoring cycles or a non-integer number of slots, the terminal may perform the operation of sleep or wake-up according to the non-integer number of slots without rounding up or reporting errors.

Optionally, the terminal may determine the duration of the second period according to the subcarrier spacing of the first frequency-domain resource, the monitoring period on the first frequency-domain resource, the subcarrier spacing of the second frequency-domain resource, the monitoring period on the second frequency-domain resource, and an N lookup table. For example, the subcarrier spacing of the first frequency domain resource is 15 x 2^M1kHz, subcarrier spacing of the second frequency domain resource is 15 x 2^M2kHz, the monitoring period of the terminal on the first frequency domain resource is L1 timeslots, the monitoring period on the second frequency domain resource is L2 timeslots, where M1 and M2 are integers greater than or equal to 0, and L1 and L2 are integers greater than or equal to 1, and the terminal may determine the duration of the second period according to table 3.

TABLE 3

It should be understood that the numerical values shown in table 3 are only examples and do not limit the present application.

In another possible implementation manner, the network device may also not use the subcarrier spacing of the first frequency-domain resource as the reference subcarrier spacing, and does not use the monitoring period of the terminal on the first frequency-domain resource as the reference monitoring period. The network device may send second configuration information to the terminal before sending the power saving information to the terminal, where the second configuration information includes a reference subcarrier interval and a reference monitoring period of the power saving signal.

Correspondingly, the terminal determines the duration of the first time period according to the reference subcarrier interval, the reference monitoring period, the subcarrier interval of the first frequency domain resource, the monitoring period of the terminal on the first frequency domain resource and the N; and determining the duration of the second time interval according to the reference subcarrier interval, the reference monitoring period, the subcarrier interval of the second frequency domain resource, the monitoring period of the terminal on the second frequency domain resource and the N.

Optionally, the terminal may further calculate a first period duration according to the reference subcarrier interval, the reference monitoring period, the subcarrier interval of the first frequency domain resource, the monitoring period on the first frequency domain resource, and N; and calculating the duration of the second time interval according to the reference subcarrier interval, the reference monitoring period, the subcarrier interval of the second frequency domain resource, the monitoring period on the second frequency domain resource and the N.

For example, if the reference subcarrier spacing is 15 x 2^M0kHz, reference monitoring period of L0 time slots, subcarrier spacing of first frequency domain resource allocation of 15 x 2^M1kHz, the monitoring period of the terminal on the first frequency domain resource is L1 time slots, wherein M0 and M1 are integers which are greater than or equal to 0, and L0 and L1 are integers which are greater than or equal to 1. The terminal determines the duration of the first period to be on the first frequency domain resource

A monitoring period of, or

A monitoring period of, or

One monitoring period, or NxL 0 x 2^M1-M0A time slot, or

A time slot, or

A time slot; the duration of the second time interval is on the second frequency domain resource

A monitoring period of, or

A monitoring period of, or

One monitoring period, or NxL 0 x 2^M2-M0A time slot, or

A time slot, or

And a time slot.

If M1 is more than or equal to M0 and M2 is more than or equal to M0, the first time interval and the second time interval are integral time slots; if M1< M0, M2< M0, the first time interval and the second time interval are non-integral number of time slots. As previously mentioned, the terminal may not expect the first time period and/or the second time period to be a non-integer number of time slots. In some embodiments, the reference subcarrier spacing may be made smaller than or equal to the subcarrier spacing of the first frequency domain resource and the reference subcarrier spacing may be made smaller than the second frequency domain resource, i.e., M1 ≧ M0, M2 ≧ M0, thereby guaranteeing the first period and the second period as an integer number of slots.

Alternatively, the terminal may report an error to the network device when determining that the first period and/or the second period are non-integer monitoring cycles or non-integer time slots. On the other hand, if the network device acquires that the first time period and/or the second time period are not expected to be a non-integer number of cycles or a non-integer number of time slots by the terminal according to the pre-arrangement or the communication with the terminal device, before the network device sends the power consumption saving signal, the network device may determine the first time period and the second time period according to the reference subcarrier interval, the reference monitoring cycle, the subcarrier interval of the first frequency domain resource, the monitoring cycle on the first frequency domain resource, the subcarrier interval of the second frequency domain resource, and the monitoring cycle on the second frequency domain resource, so that the first time period and the second time period are both values of N of the integer number of monitoring cycles or the first time period and the second time period are both values of N of the non-integer number of time slots.

Of course, the terminal may also perform the sleep or wake-up operation according to a non-integer number of monitoring periods or a non-integer number of slots.

Optionally, the terminal may determine the duration of the first period and the duration of the second period according to the information look-up table. For example, let the reference subcarrier spacing be 15 x 2^M0kHz, reference monitoring period of L0 time slots, subcarrier spacing of first frequency domain resource allocation of 15 x 2^M1kHz, a monitoring period of the terminal on the first frequency domain resource is L1 timeslots, where M0 and M1 are integers greater than or equal to 0, and L0 and L1 are integers greater than or equal to 1, and the terminal may determine the first period duration as a W monitoring period according to table 4, or determine the first period duration as Z timeslots according to table 5.

TABLE 4

TABLE 5

It should be understood that the numerical values shown in tables 4 and 5 are only examples and are not intended to limit the present application.

The terminal determines the duration of the second period in a similar manner to the first period, which is not illustrated here.

Generally, the first time interval and the second time interval comprise time slots which are continuous time slots.

Yet another embodiment, N C-DRX cycles

In both LTE and NR, the concept of C-DRX is defined, and in particular, a terminal in an RRC connected state (RRC _ connected) may be configured with a C-DRX cycle (C-DRX cycle). As shown in fig. 14, the C-DRX cycle consists of an active period (on duration) in which the terminal monitors and receives a PDCCH, and a sleep period (opportunity for DRX); during the sleep period, the UE does not receive the PDCCH to reduce power consumption. The size of the C-DRX period and the lengths of the active period and the dormant period can be configured to the terminal by the network equipment.

When the network device configures the C-DRX cycle for the terminal, in a CA scenario, different C-DRX parameters may be configured for different CCs, and in a BWP scenario, different C-DRX parameters may be configured for different BWPs, that is, the C-DRX cycles on different CCs or different BWPs may be different.

In this embodiment, the network device may further send a power consumption saving signal to the terminal according to a requirement after configuring the C-DRX parameters for the terminal on different frequency domain resources, where the power consumption saving signal sent by the network device may indicate N C-DRX cycles.

Since the lengths of the N C-DRX cycles are related to the length of one C-DRX cycle, when determining the size of N, the network device needs to consider the length of one C-DRX cycle, that is, determine the value of N according to the reference C-DRX cycle.

In one possible implementation, the C-DRX cycle on the first frequency domain resource can be taken as a reference C-DRX cycle, so the N C-DRX cycles indicated by the network device are the N C-DRX cycles on the first frequency domain resource. Accordingly, the terminal can directly determine the first period as N C-DRX cycles on the first frequency-domain resource.

The terminal may determine the duration of the second period based on the C-DRX cycle on the first frequency domain, the C-DRX cycle on the second frequency domain resource, and N.

Optionally, the terminal may further calculate the duration of the second period according to the C-DRX cycle of the first frequency domain resource, the C-DRX cycle of the second frequency domain resource, and N. For example, if the C-DRX cycle on the first frequency domain resource is K1 absolute time units, the C-DRX cycle on the second frequency domain resource is K2 absolute time units, and K1 and K2 are integers greater than or equal to 1; the terminal determines the duration of the second period to be N x K1/K2C-DRX cycles on the second frequency-domain resource.

In the above manner that the terminal determines the first period duration and the second period duration, the unit of the first period duration and the second period duration is the C-DRX cycle, and in addition, the terminal may determine the number of absolute period units included in the first period and the second period. For example, the terminal determines that the duration of the first period and the duration of the second period are each a unit of N × K1 absolute times.

Optionally, the terminal may determine the duration of the second period based on the C-DRX cycle on the first frequency domain resource, the C-DRX cycle on the second frequency domain resource, and the N look-up table. For example, the C-DRX cycle on the first frequency domain resource is K1 absolute time units, and the C-DRX cycle on the second frequency domain resource is K2 absolute time units, where the absolute time units may be milliseconds (ms), seconds(s), etc., and K1 and K2 are integers greater than or equal to 1; the terminal may determine the duration of the second period according to table 6 or table 7.

TABLE 6

It should be understood that the numerical values shown in table 6 are only examples and do not limit the present application.

In another possible implementation, the network device may not use the C-DRX cycle on the first frequency domain resource as the reference C-DRX cycle. The network device may send third configuration information to the terminal, the third configuration information including K0 absolute time units with reference to the C-DRX cycle, before sending the power consumption saving signal to the terminal.

Correspondingly, the terminal determines the duration of the first period according to the reference C-DRX cycle, the C-DRX cycle on the first frequency domain resource and the N, and determines the duration of the second period according to the reference C-DRX cycle, the C-DRX cycle on the second frequency domain resource and the N.

Optionally, the terminal may further calculate a duration of the first period according to the reference C-DRX cycle, the C-DRX cycle on the first frequency domain resource, and N; and calculating the duration of the second period according to the reference C-DRX period, the C-DRX period on the second frequency domain resource and the N.

For example, if the C-DRX cycle is K0 absolute time units, the C-DRX cycle of the first frequency domain resource is K1 absolute time units, and the C-DRX cycle of the second frequency domain resource is K2 absolute time units, where bits K0, K1, and K2 are integers greater than or equal to 1. The terminal determines the duration of the first period to be N × K0/K1C-DRX cycles on the first frequency domain resource, and the duration of the second period to be N × K0/K2C-DRX cycles on the second frequency domain resource; alternatively, the terminal may determine that the durations of the first and second periods are each N × K0 absolute time units.

In some embodiments, the terminal may not expect the duration of the first period and the duration of the second period to be a non-integer number of C-DRX cycles, and therefore, if the terminal determines that the duration of the first period and/or the duration of the second period is the non-integer number of C-DRX cycles, an error may be reported to the network device. On the other hand, if the network device acquires that the first period and/or the second period are not expected to be a non-integer number of C-DRX cycles according to the pre-arrangement or the communication with the network device, before the network device sends the power consumption saving signal, the network device may determine the first period and the second period according to the reference C-DRX cycle, the C-DRX cycle on the first frequency domain resource, and the C-DRX cycle on the second frequency domain resource, so that the first period and the second period are both values of N of the integer number of C-DRX cycles.

Alternatively, the terminal may determine the duration of the first period based on the reference C-DRX cycle, the C-DRX cycle on the first frequency domain resource, and the N look-up table. For example, assuming that the reference C-DRX cycle is K0 absolute time units and the C-DRX cycle on the first frequency domain resource is K1 absolute time units, the terminal may determine the duration of the first period as B C-DRX cycles according to Table 7, or as C absolute time units according to Table 8.

TABLE 7

TABLE 8

It should be understood that the numerical values shown in tables 7 and 8 are only examples and are not intended to limit the present application.

The terminal determines the duration of the second period in a similar manner to the first period, which is not illustrated here.

The manner of determining the duration of the first period and the second period is described above for the three cases, respectively, and the terminal should also determine the starting time of the first period and the second period when performing the sleep or wake-up operation according to the power saving signal and the network device determines whether the first signal can be transmitted to the terminal. Specifically, the determining manner of the start time of the first time interval and the second time interval may include the following four manners:

in a first way,

The terminal may take a first time slot on the first frequency domain resource after receiving the power consumption saving signal as a start time of the first period and a first time slot on the second frequency domain resource after receiving the power consumption saving signal as a start time of the second time slot. For the network device, the first time slot on the first frequency domain resource after the power consumption saving signal is transmitted may be used as the start time of the first period, and the first time slot on the second frequency domain resource after the power consumption saving signal is transmitted may be used as the start time of the second time slot, as shown in fig. 4 to 7.

Alternatively, the terminal may use the time slot in which the power consumption saving signal is received as the start time of the first period and the second period. Accordingly, the network device uses the time slot for transmitting the power saving signal as the start time of the first period and the second period, as shown in fig. 15.

The first way of determining the starting time of the first time interval and the second time interval is applicable to the first case, the second case and the third case.

The second way,

When the N time units indicated by the power consumption saving signal are N monitoring occasions, the terminal may use a first monitoring occasion on the first frequency domain resource after receiving the power consumption saving signal as a start time of the first time period, and use a first monitoring occasion on the second frequency domain resource after receiving the power consumption saving signal as a start time of the second time period. For the network device, the first monitoring opportunity on the first frequency domain resource after the power consumption saving signal is transmitted may be used as the start time of the first period, and the first monitoring opportunity on the second frequency domain resource after the power consumption saving signal is transmitted may be used as the start time of the second period, as shown in fig. 9 to 12.

The third method,

When the N time units indicated by the power saving signal are N C-DRX cycles, the terminal may take the start time of the next C-DRX on the first frequency domain resource after receiving the power saving signal as the start time of the first period and the start time of the next C-DRX on the second frequency domain resource after receiving the power saving signal as the start time of the second period. For the network device, the start time of the next C-DRX on the first frequency domain resource after the power consumption saving signal is transmitted may be taken as the start time of the first period, and the start time of the next C-DRX on the second frequency domain resource after the power consumption saving signal is transmitted may be taken as the start time of the second period.

The starting time of the C-DRX can refer to the starting time of one C-DRX cycle, and can also refer to the starting time of an active period in the C-DRX cycle.

The fourth way,

As described above, the power saving signal may be carried in a DCI signaling and sent to the terminal, and the DCI carrying the power saving signal may be a DCI dedicated to the power saving signal, or the DCI carries scheduling information for scheduling uplink data or downlink data in addition to the power saving signal. When the power consumption saving signal and the scheduling information multiplex one DCI, the terminal and the network device complete transmission of uplink data or downlink data according to the scheduling information, and then the terminal enters a sleep state.

In a possible implementation manner, if the DCI includes the power saving signal and the scheduling information of the downlink data (or the uplink data), the terminal first receives the downlink data (or transmits the uplink data to the network device) transmitted by the network device according to the DCI, and then enters the sleep state, at this time, the terminal may use a first symbol or a first slot after a last symbol of the downlink data (or the uplink data) as a start time of the first period (and/or the second period), as shown in fig. 16.

In another possible implementation manner, when the network device communicates with the terminal, a hybrid automatic repeat request (HARQ) mechanism may be introduced. After receiving the downlink data, the terminal returns an acknowledgement frame (ACK/NACK) to the network equipment to indicate whether the terminal successfully receives the downlink data, and if the reception fails, the network equipment can resend the scheduling information and resend the downlink data; after the terminal sends the uplink data to the network device, if the network device fails to receive the uplink data, the terminal may send the scheduling information to the terminal again, so that the terminal resends the uplink data, as shown in fig. 17.

If the DCI is scheduled to be downlink data, the terminal may use a time slot in which a power saving signal (DCI) is received as a starting time of a first time period; or, a first symbol or a first time slot after the terminal receives the last symbol of the downlink data may be used as the starting time of the first period; or, the first symbol or the first slot after the terminal sends the ACK/NACK may be used as the starting time of the first period; or, the terminal may also wait for a preset time period after sending the ACK/NACK, and the terminal does not receive the scheduling information of the network device within the preset time period, that is, the terminal starts to enter the sleep state again without performing retransmission.

Specifically, if the terminal uses the time slot in which the power saving signal (DCI) is received as the start time of the first time period, the terminal needs to receive downlink data and feed back ACK/NACK according to the DCI, wait for a preset time period to determine that retransmission is not performed, and then really enter the sleep state. For example, as shown in fig. 18, the terminal receives DCI in slot 0, where the DCI includes scheduling information of downlink data and a power saving signal, and indicates that the terminal receives the downlink data in slot 0 and can enter a sleep state in the next 5 slots. The terminal determines that the time slot 0 is the starting time of a first period, and the duration of the first period is 5 time slots (namely, time slots 0-4); the terminal receives downlink data in the time slot 0 and feeds back ACK/NACK on the time slot 1, assuming that the preset time duration is 2 time slots, if the terminal does not receive scheduling information sent by the network device in 2 time slots (i.e., time slot 2 and time slot 3) after the ACK/NACK is fed back, the terminal enters a sleep state from the time slot 4.

If the terminal uses the first symbol or the first time slot after receiving the last symbol of the downlink data as the starting time of the first time interval, the terminal needs to feed back ACK/NACK and wait for a preset time period, and then can enter the sleep state. For example, as shown in fig. 18, the terminal receives DCI in slot 0, where the DCI includes scheduling information of downlink data and a power saving signal, and indicates that the terminal receives the downlink data in slot 0 and can enter a sleep state in the next 5 slots. The terminal determines that the time slot 1 is the starting time of a first period, and the duration of the first period is 5 time slots (namely, the time slots 1-5); the terminal feeds back ACK/NACK on the timeslot 1, assuming that the preset duration is 2 timeslots, if the terminal does not receive scheduling information sent by the network device in 2 timeslots (i.e., timeslot 2 and timeslot 3) after feeding back ACK/NACK, the terminal enters a sleep state from timeslot 4, that is, the terminal is in a sleep state on timeslot 4 and timeslot 5.

If the terminal uses the first symbol or the first time slot after sending the ACK/NACK as the starting time of the first time period, the terminal needs to wait for a preset duration, and can really enter the sleep state when the network device does not resend the scheduling information. For example, as shown in fig. 18, the terminal receives DCI in slot 0, receives downlink data in slot 0, and feeds back ACK/NACK in slot 1, the terminal may use slot 2 as the start time of the first period, assuming that the preset time duration is 2 slots, and if the terminal does not receive scheduling information sent by the network device in 2 slots (i.e., slot 2 and slot 3) after the ACK/NACK is fed back, the terminal enters a sleep state from slot 4, that is, the terminal is in a sleep state in slots 4 to 6.

And if the terminal starts timing of the first time period after feeding back the ACK/NACK and waiting for the preset time length, the first time period is the time period when the terminal really enters the sleep state. For example, as shown in fig. 18, the terminal receives DCI in slot 0, where the DCI includes scheduling information of downlink data and a power saving signal, and indicates that the terminal receives the downlink data in slot 0 and can enter a sleep state in the next 5 slots. The terminal receives downlink data on a time slot 0, feeds back ACK/NACK on a time slot 1, and if the preset time length is 2 time slots, if the terminal does not receive scheduling information sent by network equipment in 2 time slots (namely, time slot 2 and time slot 3) after the ACK/NACK is fed back, the time slot 4 is taken as the starting time of a first period, namely, the terminal is in a sleep state on the time slots 4-8.

On the other hand, if the DCI is scheduled to be uplink data, the terminal may use a time slot in which a power saving signal (DCI) is received as the start time of the first time period, or may use a first symbol or a first time slot after the terminal sends a last symbol of the uplink data as the start time of the first time period, or may wait for a preset time period after sending the uplink data, and the terminal does not receive scheduling information of the network device within the preset time period, that is, does not need to perform retransmission, and then starts to enter the sleep state. Similar to the case of downlink data scheduling by DCI, details are not repeated here.

The preset duration may be configured for the terminal by the network device.

The fifth way,

The starting time of the first period may be any one of the first to fourth manners, and the starting time of the second period is the same as the starting time of the first period.

For example, as shown in (b) of fig. 8, the terminal determines the start time of the first period as the first slot or the first monitoring opportunity on the CC1 after receiving the power consumption saving signal, and the terminal regards the start time of the first period as the start time of the second period, which is at the middle position of one slot on the CC2, which is also not the monitoring opportunity.

No matter which way is adopted to determine the starting time of the first time interval and the second time interval, the terminal and the network device need to determine the starting time in the same way according to the prior agreement or the communication between the terminal and the network device.

In the above embodiment, after receiving the power consumption saving signal, the terminal determines the time periods corresponding to the N time units indicated by the signal on different frequency domain resources, instead of simply determining that the sleep time or the wake-up time on different frequency domain resources are both N time units. The states of the terminals on different frequency domain resources are close to synchronization, so that the power consumption is saved.

Based on the same technical concept, the embodiment of the present application further provides a communication method, where the communication method includes:

the network device sends a power saving signal to the terminal, the power saving signal indicating N time units, N being a number greater than 0. The terminal determines a state of the terminal for a first time period corresponding to the N time units on the first frequency domain resource and a state for a second time period corresponding to the N time units on the second frequency domain resource. The state of the terminal comprises a sleep state and an awakening state, the sleep state represents that the terminal does not measure, and the awakening state represents that the terminal measures according to the configuration parameters.

For example, the terminal receives the CSI-RS sent by the network device, performs channel state measurement according to the CSI-RS, and feeds back a measurement result to the base station according to configuration or indication information of the network device, so that the base station optimizes data scheduling of the terminal according to the measurement result. If the terminal receives the power consumption saving signal sent by the network equipment and indicates that the terminal enters the sleep state, the terminal determines that the first time period on the first frequency domain resource does not perform channel state measurement any more and determines that the second time period on the second frequency domain resource does not perform channel state measurement any more.

Optionally, the terminal does not perform measurement after entering the sleep state, and may refer to that the terminal does not receive the CSI-RS, or may refer to that the terminal receives the CSI-RS but does not process the CSI-RS.

The determination method of the duration and the starting time of the first time interval and the duration and the starting time of the second time interval are similar to the foregoing embodiments, and are not repeated here.

Based on the same technical concept, the embodiment of the present application further provides a terminal, which is used for implementing the functions executed by the terminal in the foregoing method embodiment. As shown in fig. 19, the terminal may include a receiving unit 1901 and a processing unit 1902. The receiving unit 1901 is configured to implement the receiving of the power saving signal and the monitoring of the first signal in the foregoing method embodiment, and the processing unit 1902 is configured to perform other functions of the terminal in the foregoing method embodiment.

Based on the same technical concept, the embodiment of the present application further provides a network device, which is used for implementing the functions executed by the network device in the foregoing method embodiments. As shown in fig. 20, the terminal may include a transmitting unit 2001 for implementing the transmitting power saving signal and transmitting the first signal in the above method embodiment, and a processing unit 2002 for executing other functions of the network device in the above method embodiment.

It should be noted that the division of each unit is only a division of a logic function, and all or part of the actual implementation may be integrated into one physical entity, or may be physically separated. And these units can be implemented entirely in software, invoked by a processing element; or may be implemented entirely in hardware; and part of the units can be realized in the form of calling by a processing element through software, and part of the units can be realized in the form of hardware. For example, the receiving unit and the processing unit may be integrated together or may be implemented independently. The processing element described herein may be an integrated circuit having signal processing capabilities. In implementation, the steps of the method or the units above may be implemented by hardware integrated logic circuits in a processor element or instructions in software. Further, the above transmission unit is a unit that controls transmission, and information can be transmitted by a transmission device such as an antenna and a radio frequency device. Similarly, the receiving unit may also receive information via a receiving device, such as an antenna and a radio frequency device.

The above units may be one or more integrated circuits configured to implement the above methods, for example: one or more Application Specific Integrated Circuits (ASICs), or one or more microprocessors, or one or more Field Programmable Gate Arrays (FPGAs), etc. For another example, when the above units are implemented in the form of a processing element scheduler, the processing element may be a general-purpose processor, such as a Central Processing Unit (CPU) or other processor capable of calling programs. As another example, these units may be integrated together and implemented in the form of a system-on-a-chip (SOC).

Based on the same technical concept, the embodiment of the present application further provides a communication device, which is used for implementing the functions of the terminal in the foregoing method embodiments. As shown in fig. 21, the communication device 2100 may include a processor 2101 and a communication interface 2102. Further, the communication device 2100 may also include a memory 2103, a communication bus 2104.

In particular, the processor 2101 may be a general purpose CPU, microprocessor, ASIC, or one or more integrated circuits configured to control the execution of the programs of the present application.

The communication interface 2102 may be any device, such as a transceiver, for communicating with other devices or communication networks, such as an ethernet, a Radio Access Network (RAN), a Wireless Local Area Network (WLAN), etc.

The communication bus 2104 may include a path that conveys information between the aforementioned components.

The memory 2103 may be, but is not limited to, a read-only memory (ROM) or other type of static storage device that may store static information and instructions, a Random Access Memory (RAM) or other type of dynamic storage device that may store information and instructions, an electrically erasable programmable read-only memory (EEPROM) or any other medium that can be used to carry or store desired program code in the form of instructions or data structures and that can be accessed by a computer. The memory 2103, which may be separate and apart, such as off-chip memory, is coupled to the processor 2101 via the communication bus 2104. The memory 2103 may also be integrated with the processor 2101.

The communication interface 2102 is responsible for communication with other devices or communication networks, and the processor 2101 is used to implement other functions in the communication methods provided by the above-described embodiments of the present application.

In particular implementations, processor 2101 may include one or more CPUs as an example.

In particular implementations, the terminal may include multiple processors, as one embodiment. Each of these processors may be a single-core (single-CPU) processor or a multi-core (multi-CPU) processor. A processor herein may refer to one or more devices, circuits, and/or processing cores for processing data (e.g., computer program instructions).

Based on the same technical concept, the embodiment of the present application further provides a communication device, which is used for implementing the functions of the network device in the foregoing method embodiments. As shown in fig. 22, the communication device 2200 may include a processor 2201 and a communication interface 2202. Further, the communication device 2200 may also include a memory 2203, a communication bus 2204.

Specifically, the processor 2201 may be a general purpose CPU, microprocessor, ASIC, or one or more integrated circuits for controlling the execution of programs in accordance with the present invention.

Communications interface 2202, using any transceiver or the like, for communicating with other devices or communications networks, such as ethernet, RAN, WLAN, etc.

The communication bus 2204 may include a path that conveys information between the aforementioned components.

Memory 2003 may be, but is not limited to, a read-only memory or other type of static storage device that may store static information and instructions, a random access memory or other type of dynamic storage device that may store information and instructions, an electrically erasable programmable read-only memory or any other medium that can be used to carry or store desired program code in the form of instructions or data structures and that can be accessed by a computer. The memory 2203, which may be separate, such as off-chip memory, is coupled to the processor 2201 via a communication bus 2204. The memory 2203 may also be integrated with the processor 2201.

The communication interface 2202 is responsible for communicating with other devices or communication networks, and the processor 2201 is used for implementing other functions in the communication methods provided by the above-described embodiments of the present application.

In particular implementations, processor 2201 may include one or more CPUs, as one embodiment.

In particular implementations, the terminal may include multiple processors, as one embodiment. Each of these processors may be a single core processor or a multi-core processor. A processor herein may refer to one or more devices, circuits, and/or processing cores for processing data (e.g., computer program instructions).

Based on the same technical concept, the embodiment of the present application provides a computer-readable storage medium storing computer instructions, which, when executed on a computer, cause the computer to perform the functions performed by the terminal in the above method embodiments.

Based on the same technical concept, the embodiment of the present application provides a computer-readable storage medium, which stores computer instructions, and when the instructions are executed on a computer, the instructions cause the computer to perform the functions performed by the network device in the above method embodiments.

Based on the same technical concept, the embodiments of the present application provide a computer program product containing instructions, which when run on a computer, cause the computer to perform the functions performed by the terminal in the above-mentioned method embodiments.

Based on the same technical concept, the embodiments of the present application provide a computer program product containing instructions, which when run on a computer, cause the computer to perform the functions performed by the network device in the above-mentioned method embodiments.

Based on the same technical concept, the present application provides a chip, where the chip is connected to a memory and is configured to read and execute a software program stored in the memory, so as to implement the functions executed by the terminal in the foregoing method embodiments.

Based on the same technical concept, the present application provides a chip, where the chip is connected to a memory, and is configured to read and execute a software program stored in the memory, so as to implement the functions performed by the network device in the foregoing method embodiments.

In the above embodiments of the present application, "and/or" describes an association relationship of associated objects, indicating that three relationships may exist, for example, a and/or B may indicate: a exists alone, A and B exist simultaneously, and B exists alone. The character "/" generally indicates that the former and latter associated objects are in an "or" relationship.

In the embodiments of the present application, the plural number means two or more.

In addition, it is to be understood that the terms first, second, etc. in the description of the present application are used for distinguishing between the descriptions and not necessarily for describing a sequential or chronological order.

It will be apparent to those skilled in the art that various changes and modifications may be made in the present application without departing from the spirit and scope of the application. Thus, if such modifications and variations of the present application fall within the scope of the claims of the present application and their equivalents, the present application is intended to include such modifications and variations as well.

Claims (20)

1. A method of communication, comprising:

a terminal receives a power consumption saving signal sent by network equipment, wherein the power consumption saving signal indicates N time units, and N is an integer greater than 0;

the terminal determines the state of the terminal in a first time interval corresponding to the N time units on a first frequency domain resource and the state of the terminal in a second time interval corresponding to the N time units on a second frequency domain resource according to the power consumption saving signal;

the state is a sleep state or an awakening state, the sleep state represents that the terminal does not monitor the first signal, and the awakening state represents that the terminal monitors the first signal according to the configuration parameters.

2. The method of claim 1, wherein the time unit is a time slot, and wherein the duration of the first period is N time slots of the first frequency domain resource;

and the duration of the second time interval is determined according to the subcarrier interval configured by the first frequency domain resource, the subcarrier interval configured by the second frequency domain resource and the N time units.

3. The method of claim 2, wherein the first frequency domain resource configuration is subcarrier spaced 15 x 2 apart^M1kHz, subcarrier spacing of said second frequency domain resource configuration 15 x 2^M2kHz, wherein M1 and M2 are integers greater than or equal to 0;

the duration of the second time interval is N x 2 of the second frequency domain resource^M2-M1A time slot, or

A time slot, or

And a time slot.

4. The method of claim 1, wherein the time unit is a time slot;

before the terminal receives the power consumption saving signal sent by the network device, the method further includes: the terminal receives first configuration information sent by the network equipment, wherein the first configuration information comprises a reference subcarrier interval of the power consumption saving signal;

the terminal determines the duration of the first time period according to the reference subcarrier interval, the subcarrier interval configured by the first frequency domain resource and the N time units;

and the terminal determines the duration of the second time period according to the reference subcarrier interval, the subcarrier interval configured by the second frequency domain resource and the N time units.

5. The method of claim 4, wherein the reference subcarrier spacing is 15 x 2^M0kHz, subcarrier spacing of said first frequency domain resource configuration 15 x 2^M1kHz, subcarrier spacing of said second frequency domain resource configuration 15 x 2^M2kHz；

The duration of the first time interval is N x 2 of the first frequency domain resource^M1-M0A time slot, or

A time slot, or

A time slot;

the duration of the second time interval is N x 2 of the second frequency domain resource^M2-M0A time slot, or

A time slot, or

And a time slot.

6. The method of claim 1, wherein the time unit is a monitoring opportunity;

the duration of the first period is N monitoring cycles on the first frequency domain resource, or N × L1 time slots, where L denotes that the monitoring cycle of the terminal on the first frequency domain resource is L1 time slots, and L1 is an integer greater than or equal to 1;

and the duration of the second time interval is determined according to the subcarrier interval configured by the first frequency domain resource, the subcarrier interval configured by the second frequency domain resource, the monitoring period of the terminal on the first frequency domain resource, the monitoring period of the terminal on the second frequency domain resource and the N time units.

7. The method of claim 6, wherein the first frequency domain resource configuration is subcarrier spaced 15 x 2 apart^M1kHz, subcarrier spacing of said second frequency domain resource configuration 15 x 2^M2kHz, wherein the monitoring period of the terminal on the second frequency domain resource is L2 time slots, M1 and M2 are integers which are greater than or equal to 0, and L2 is an integer which is greater than or equal to 1;

the duration of the second time interval is on the second frequency domain resource

A monitoring period of, or

A monitoring period of, or

One monitoring period, or NxL 1 x 2^M2-M1A time slot, or

A time slot, or

And a time slot.

8. The method of claim 1, wherein the time unit is a monitoring opportunity;

before the terminal receives the power consumption saving signal sent by the network device, the method further includes: the terminal receives second configuration information sent by the network equipment, wherein the second configuration information comprises a reference subcarrier interval and a reference monitoring period of the power consumption saving signal;

the terminal determines the duration of the first time period according to the reference subcarrier interval, the subcarrier interval configured by the first frequency domain resource, the reference monitoring period, the monitoring period of the terminal on the first frequency domain resource and the N time units;

and the terminal determines the duration of the second time period according to the reference subcarrier interval, the subcarrier interval configured by the second frequency domain resource, the reference monitoring period, the monitoring period of the terminal on the second frequency domain resource and the N time units.

9. The method of claim 8, wherein the reference subcarrier spacing is 15 x 2^M0kHz, a reference monitoring period is L0 time slots, M0 is an integer greater than or equal to 0, and L0 is an integer greater than or equal to 1;

subcarrier spacing 15 x 2 of the first frequency domain resource configuration^M1kHz, subcarrier spacing of said second frequency domain resource configuration 15 x 2^M2kHz, the monitoring period of the terminal on the first frequency domain resource is L1 time slots, the monitoring period of the terminal on the second frequency domain resource is L2 time slots, wherein M1 and M2 are integers which are greater than or equal to 0, and L1 and L2 are integers which are greater than or equal to 1;

the duration of the first time interval is on the first frequency domain resource

A monitoring period of, or

A monitoring period of, or

One monitoring period, or NxL 0 x 2^M1-M0A time slot, or

A time slot, or

A time slot；

The duration of the second time interval is on the second frequency domain resource

A monitoring period of, or

A monitoring period of, or

One monitoring period, or NxL 0 x 2^M2-M0A time slot, or

A time slot, or

And a time slot.

10. The method of claim 1, wherein the time units are discontinuous reception (C-DRX) cycles in a connected state, the C-DRX cycle of the first frequency domain resource configuration is K1 absolute time units, K1 is an integer greater than or equal to 1;

the duration of the first period is N C-DRX cycles, or N x K1 absolute time units, on the first frequency domain resource;

the duration of the second period is determined according to the C-DRX cycle configured by the terminal on the first frequency domain resource, the C-DRX cycle configured by the terminal on the second frequency domain resource and the N time units.

11. The method of claim 10, wherein the C-DRX cycle of the second frequency domain resource configuration is K2 absolute time units, K2 is an integer greater than or equal to 1;

the duration of the second time interval is N x K1/K2C-DRX cycles or N x K1 absolute time units on the second frequency domain resource.

12. The method of claim 1, wherein the unit of time is a C-DRX cycle;

before the terminal receives the power consumption saving signal sent by the network device, the method further includes: the terminal receives third configuration information sent by the network equipment, wherein the third configuration information comprises that the reference C-DRX cycle of the power consumption saving signal is K0 absolute time units;

the terminal determines the duration of the first period according to the reference C-DRX cycle, the C-DRX cycle configured by the terminal in the first frequency domain resource and the N time units;

and the terminal determines the duration of the second period according to the reference C-DRX cycle, the C-DRX cycle configured by the terminal in the second frequency domain resource and the N time units.

13. The method of claim 12, wherein the C-DRX cycle of the first frequency-domain resource configuration is K1 absolute time units, the C-DRX cycle of the second frequency-domain resource configuration is K2 absolute time units, K1, K2 are integers greater than or equal to 1;

the duration of the first time interval is N x K0/K1C-DRX cycles or N x K0 absolute time units on the first frequency domain resource;

the duration of the second time interval is N x K0/K2C-DRX cycles or N x K0 absolute time units on the second frequency domain resource.

14. A method of communication, comprising:

the method comprises the steps that network equipment sends a power consumption saving signal to a terminal, wherein the power consumption saving signal indicates N time units, N is a number larger than 0 and is used for indicating the state of the terminal in a first time period corresponding to the N time units on a first frequency domain resource and a second time period corresponding to the N time units on a second frequency domain resource, the state is a sleep state or an awakening state, the sleep state indicates that the terminal does not monitor a first signal, and the awakening state monitors the first signal according to configuration parameters;

and the network equipment sends the first signal or does not send the first signal to the terminal according to the state.

15. The method of claim 14, wherein the time unit is a time slot, and wherein the duration of the first period is N time slots of the first frequency domain resource;

and the duration of the second time interval is determined according to the subcarrier interval configured by the first frequency domain resource, the subcarrier interval configured by the second frequency domain resource and the N time units.

16. The method of claim 14, wherein the time unit is a time slot;

before the network device sends a power saving signal to a terminal, the method further comprises: the network equipment sends first configuration information to the terminal, wherein the first configuration information comprises a reference subcarrier interval of the power consumption saving signal;

the duration of the first time interval is determined according to the reference subcarrier interval, the subcarrier interval of the first frequency domain resource allocation and the N time units;

and the duration of the second time interval is determined according to the reference subcarrier interval, the subcarrier interval configured by the second frequency domain resource and the N time units.

17. The method of claim 14, wherein the time unit is a monitoring opportunity;

the duration of the first period is N monitoring cycles on the first frequency domain resource, or N × L1 time slots, where L denotes that the monitoring cycle of the terminal on the first frequency domain resource is L1 time slots, and L1 is an integer greater than or equal to 1;

and the duration of the second time interval is determined according to the subcarrier interval configured by the first frequency domain resource, the subcarrier interval configured by the second frequency domain resource, the monitoring period of the terminal on the first frequency domain resource, the monitoring period of the terminal on the second frequency domain resource and the N time units.

18. The method of claim 14, wherein the time unit is a monitoring opportunity;

before the network device sends a power saving signal to a terminal, the method further comprises: the network equipment sends second configuration information to the terminal, wherein the second configuration information comprises a reference subcarrier interval and a reference monitoring period of the power consumption saving signal;

the duration of the first time interval is determined according to the reference subcarrier interval, the subcarrier interval configured by the first frequency domain resource, the reference monitoring period, the monitoring period of the terminal on the first frequency domain resource, and the N time units;

and the duration of the second time interval is determined according to the reference subcarrier interval, the subcarrier interval configured by the second frequency domain resource, the reference monitoring period, the monitoring period of the terminal on the second frequency domain resource and the N time units.

19. A communication device, comprising: a processor and a communication interface, the processor coupled with a memory and the communication interface;

the communication interface is used for communicating with other equipment;

the processor is configured to execute instructions or programs in the memory to cause the communication device to perform the method of any of claims 1-13.

20. A communication device, comprising: a processor and a communication interface, the processor coupled with a memory and the communication interface;

the communication interface is used for communicating with other equipment;

the processor is configured to execute instructions or programs in the memory to cause the communication device to perform the method of any of claims 14-17.

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